freebsd-nq/libexec/rtld-aout/rtld.c
2002-05-28 18:57:20 +00:00

2551 lines
66 KiB
C

/*
* Copyright (c) 1993 Paul Kranenburg
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by Paul Kranenburg.
* 4. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* $FreeBSD$
*/
#include <sys/param.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <sys/file.h>
#include <sys/time.h>
#include <sys/resource.h>
#include <sys/errno.h>
#include <sys/mman.h>
#ifndef MAP_COPY
#define MAP_COPY MAP_PRIVATE
#endif
#include <dlfcn.h>
#include <err.h>
#include <fcntl.h>
#include <a.out.h>
#include <paths.h>
#include <stab.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <stdarg.h>
#include <link.h>
#include "md.h"
#include "shlib.h"
#include "support.h"
#include "dynamic.h"
#ifndef MAP_ANON
#define MAP_ANON 0
#define anon_open() do { \
if ((anon_fd = open(_PATH_DEVZERO, O_RDWR, 0)) == -1) \
err("open: %s", _PATH_DEVZERO); \
} while (0)
#define anon_close() do { \
(void)close(anon_fd); \
anon_fd = -1; \
} while (0)
#else
#define anon_open()
#define anon_close()
#endif
/*
* Structure for building a list of shared objects.
*/
struct so_list {
struct so_map *sol_map; /* Link map for shared object */
struct so_list *sol_next; /* Next entry in the list */
};
/*
* Loader private data, hung off <so_map>->som_spd
*/
struct somap_private {
int spd_version;
struct so_map *spd_parent;
struct so_list *spd_children;
struct so_map *spd_prev;
dev_t spd_dev;
ino_t spd_ino;
int spd_refcount;
int spd_flags;
#define RTLD_MAIN 0x01
#define RTLD_RTLD 0x02
#define RTLD_DL 0x04
#define RTLD_INIT 0x08
unsigned long a_text; /* text size, if known */
unsigned long a_data; /* initialized data size */
unsigned long a_bss; /* uninitialized data size */
#ifdef SUN_COMPAT
long spd_offset; /* Correction for Sun main programs */
#endif
};
#define LM_PRIVATE(smp) ((struct somap_private *)(smp)->som_spd)
#ifdef SUN_COMPAT
#define LM_OFFSET(smp) (LM_PRIVATE(smp)->spd_offset)
#else
#define LM_OFFSET(smp) (0)
#endif
/* Base address for section_dispatch_table entries */
#define LM_LDBASE(smp) (smp->som_addr + LM_OFFSET(smp))
/* Start of text segment */
#define LM_TXTADDR(smp) (smp->som_addr == (caddr_t)0 ? PAGSIZ : 0)
/* Start of run-time relocation_info */
#define LM_REL(smp) ((struct relocation_info *) \
(smp->som_addr + LM_OFFSET(smp) + LD_REL((smp)->som_dynamic)))
/* Start of symbols */
#define LM_SYMBOL(smp, i) ((struct nzlist *) \
(smp->som_addr + LM_OFFSET(smp) + LD_SYMBOL((smp)->som_dynamic) + \
i * (LD_VERSION_NZLIST_P(smp->som_dynamic->d_version) ? \
sizeof(struct nzlist) : sizeof(struct nlist))))
/* Start of hash table */
#define LM_HASH(smp) ((struct rrs_hash *) \
((smp)->som_addr + LM_OFFSET(smp) + LD_HASH((smp)->som_dynamic)))
/* Start of strings */
#define LM_STRINGS(smp) ((char *) \
((smp)->som_addr + LM_OFFSET(smp) + LD_STRINGS((smp)->som_dynamic)))
/* Start of search paths */
#define LM_PATHS(smp) ((char *) \
((smp)->som_addr + LM_OFFSET(smp) + LD_PATHS((smp)->som_dynamic)))
/* End of text */
#define LM_ETEXT(smp) ((char *) \
((smp)->som_addr + LM_TXTADDR(smp) + LD_TEXTSZ((smp)->som_dynamic)))
/* Needed shared objects */
#define LM_NEED(smp) ((struct sod *) \
((smp)->som_addr + LM_TXTADDR(smp) + LD_NEED((smp)->som_dynamic)))
/* PLT is in data segment, so don't use LM_OFFSET here */
#define LM_PLT(smp) ((jmpslot_t *) \
((smp)->som_addr + LD_PLT((smp)->som_dynamic)))
/* Parent of link map */
#define LM_PARENT(smp) (LM_PRIVATE(smp)->spd_parent)
#ifndef RELOC_EXTERN_P
#define RELOC_EXTERN_P(s) ((s)->r_extern)
#endif
#ifndef RELOC_SYMBOL
#define RELOC_SYMBOL(s) ((s)->r_symbolnum)
#endif
#ifndef RELOC_PCREL_P
#define RELOC_PCREL_P(s) ((s)->r_pcrel)
#endif
#define END_SYM "_end"
static char __main_progname[] = "main";
static char *main_progname = __main_progname;
static char us[] = "/usr/libexec/ld.so";
char **environ;
char *__progname;
int errno;
static uid_t uid, euid;
static gid_t gid, egid;
static int careful;
static int anon_fd = -1;
static char *ld_bind_now;
static char *ld_ignore_missing_objects;
static char *ld_library_path;
static char *ld_preload;
static char *ld_tracing;
static char *ld_suppress_warnings;
static char *ld_warn_non_pure_code;
struct so_map *link_map_head;
struct so_map *link_map_tail;
struct rt_symbol *rt_symbol_head;
static void *__dlopen __P((const char *, int));
static int __dlclose __P((void *));
static void *__dlsym __P((void *, const char *));
static const char *__dlerror __P((void));
static void __dlexit __P((void));
static void *__dlsym3 __P((void *, const char *, void *));
static int __dladdr __P((const void *, Dl_info *));
static struct ld_entry ld_entry = {
__dlopen, __dlclose, __dlsym, __dlerror, __dlexit, __dlsym3, __dladdr
};
void xprintf __P((char *, ...));
static struct so_map *map_object __P(( const char *,
struct sod *,
struct so_map *));
static int map_preload __P((void));
static int map_sods __P((struct so_map *));
static int reloc_dag __P((struct so_map *, int));
static void unmap_object __P((struct so_map *, int));
static struct so_map *alloc_link_map __P(( const char *, struct sod *,
struct so_map *, caddr_t,
struct _dynamic *));
static void init_link_map __P(( struct so_map *,
struct somap_private *,
const char *, struct sod *,
struct so_map *, caddr_t,
struct _dynamic *));
static void free_link_map __P((struct so_map *));
static inline int check_text_reloc __P(( struct relocation_info *,
struct so_map *,
caddr_t));
static int reloc_map __P((struct so_map *, int));
static void reloc_copy __P((struct so_map *));
static void init_dag __P((struct so_map *));
static void init_sods __P((struct so_list *));
static void init_internal_malloc __P((void));
static void init_external_malloc __P((void));
static int call_map __P((struct so_map *, char *));
static char *findhint __P((char *, int, int *));
static char *rtfindlib __P((char *, int, int, int));
static char *rtfindfile __P((const char *));
void binder_entry __P((void));
long binder __P((jmpslot_t *));
static struct nzlist *lookup __P((char *, struct so_map **, int));
static inline struct rt_symbol *lookup_rts __P((char *, unsigned long));
static struct nzlist *lookup_in_obj __P((char *, unsigned long,
struct so_map *, int));
static struct rt_symbol *enter_rts __P((char *, unsigned long, long, int,
caddr_t, long, struct so_map *));
static void *sym_addr __P((char *));
static struct nzlist * lookup_errno_hack(char *, struct so_map **, int);
static void die __P((void));
static void generror __P((char *, ...));
static int maphints __P((void));
static void unmaphints __P((void));
static void ld_trace __P((struct so_map *));
static void rt_readenv __P((void));
static int hinthash __P((char *, int));
int rtld __P((int, struct crt_ldso *, struct _dynamic *));
/*
* Compute a hash value for symbol tables. Don't change this -- the
* algorithm is dictated by the way the linker builds the symbol
* tables in the shared objects.
*/
static inline unsigned long
sym_hash(s)
const char *s;
{
unsigned long h;
h = 0;
while (*s != '\0')
h = (h << 1) + *s++;
return h & 0x7fffffffUL;
}
static inline int
strcmp (register const char *s1, register const char *s2)
{
while (*s1 == *s2++)
if (*s1++ == 0)
return (0);
return (*(unsigned char *)s1 - *(unsigned char *)--s2);
}
#include "md-static-funcs.c"
/*
* Called from assembler stub that has set up crtp (passed from crt0)
* and dp (our __DYNAMIC).
*/
int
rtld(version, crtp, dp)
int version;
struct crt_ldso *crtp;
struct _dynamic *dp;
{
struct relocation_info *reloc;
struct relocation_info *reloc_limit; /* End+1 of relocation */
struct so_debug *ddp;
struct so_map *main_map;
struct so_map *smp;
char *add_paths;
char *main_path;
/* Check version */
if (version != CRT_VERSION_BSD_2 &&
version != CRT_VERSION_BSD_3 &&
version != CRT_VERSION_BSD_4 &&
version != CRT_VERSION_BSD_5 &&
version != CRT_VERSION_SUN)
return -1;
/* Fixup __DYNAMIC structure */
(long)dp->d_un.d_sdt += crtp->crt_ba;
/* Relocate ourselves */
reloc = (struct relocation_info *) (LD_REL(dp) + crtp->crt_ba);
reloc_limit =
(struct relocation_info *) ((char *) reloc + LD_RELSZ(dp));
while(reloc < reloc_limit) {
/*
* Objects linked with "-Bsymbolic" (in particular, ld.so
* itself) can end up having unused relocation entries at
* the end. These can be detected by the fact that they
* have an address of 0.
*/
if(reloc->r_address == 0) /* We're done */
break;
md_relocate_simple(reloc, crtp->crt_ba,
reloc->r_address + crtp->crt_ba);
++reloc;
}
if (version >= CRT_VERSION_BSD_4)
__progname = crtp->crt_ldso;
if (version >= CRT_VERSION_BSD_3)
main_progname = crtp->crt_prog;
main_path = version >= CRT_VERSION_BSD_5 ? crtp->crt_argv[0] :
main_progname;
/* Some buggy versions of crt0.o have crt_ldso filled in as NULL. */
if (__progname == NULL)
__progname = us;
/* Fill in some fields in _DYNAMIC or crt structure */
if (version >= CRT_VERSION_BSD_4)
crtp->crt_ldentry = &ld_entry; /* crt */
else
crtp->crt_dp->d_entry = &ld_entry; /* _DYNAMIC */
/* Initialize our internal malloc package. */
init_internal_malloc();
/* Setup out (private) environ variable */
environ = crtp->crt_ep;
/* Get user and group identifiers */
uid = getuid(); euid = geteuid();
gid = getgid(); egid = getegid();
careful = (uid != euid) || (gid != egid);
rt_readenv();
anon_open();
/* Make a link map entry for the main program */
main_map = alloc_link_map(main_path,
(struct sod *) NULL, (struct so_map *) NULL,
(caddr_t) 0, crtp->crt_dp);
LM_PRIVATE(main_map)->spd_refcount++;
LM_PRIVATE(main_map)->spd_flags |= RTLD_MAIN;
/* Make a link map entry for ourselves */
smp = alloc_link_map(us,
(struct sod *) NULL, (struct so_map *) NULL,
(caddr_t) crtp->crt_ba, dp);
LM_PRIVATE(smp)->spd_refcount++;
LM_PRIVATE(smp)->spd_flags |= RTLD_RTLD;
/*
* Setup the executable's run path
*/
if (version >= CRT_VERSION_BSD_4) {
add_paths = LM_PATHS(main_map);
if (add_paths)
add_search_path(add_paths);
}
/*
* Setup the directory search list for findshlib. We use only
* the standard search path. Any extra directories from
* LD_LIBRARY_PATH are searched explicitly, in rtfindlib.
*/
std_search_path();
/* Map in LD_PRELOADs before the main program's shared objects so we
can intercept those calls */
if (ld_preload != NULL) {
if(map_preload() == -1) /* Failed */
die();
}
/* Map all the shared objects that the main program depends upon */
if(map_sods(main_map) == -1)
die();
if(ld_tracing) { /* We're done */
ld_trace(link_map_head);
exit(0);
}
crtp->crt_dp->d_un.d_sdt->sdt_loaded = link_map_head->som_next;
/* Relocate all mapped objects. */
if(reloc_dag(main_map, ld_bind_now != NULL) == -1) /* Failed */
die();
/*
* Switch to the same malloc that the program uses. We do
* this before initializing the loaded objects, because their
* initialization functions may well call malloc, and it won't
* work right until we have set it up.
*/
init_external_malloc();
/* Initialize all mapped objects. */
init_dag(main_map);
ddp = crtp->crt_dp->d_debug;
ddp->dd_cc = rt_symbol_head;
if (ddp->dd_in_debugger) {
caddr_t addr = (caddr_t)((long)crtp->crt_bp & (~(PAGSIZ - 1)));
/* Set breakpoint for the benefit of debuggers */
if (mprotect(addr, PAGSIZ,
PROT_READ|PROT_WRITE|PROT_EXEC) == -1) {
err(1, "Cannot set breakpoint (%s)", main_progname);
}
md_set_breakpoint((long)crtp->crt_bp, (long *)&ddp->dd_bpt_shadow);
if (mprotect(addr, PAGSIZ, PROT_READ|PROT_EXEC) == -1) {
err(1, "Cannot re-protect breakpoint (%s)",
main_progname);
}
ddp->dd_bpt_addr = crtp->crt_bp;
if (link_map_head)
ddp->dd_sym_loaded = 1;
}
/* Close the hints file */
unmaphints();
/* Close our file descriptor */
(void)close(crtp->crt_ldfd);
anon_close();
return LDSO_VERSION_HAS_DLADDR;
}
void
ld_trace(smp)
struct so_map *smp;
{
char *fmt1, *fmt2, *fmt, *main_local;
int c;
if ((main_local = getenv("LD_TRACE_LOADED_OBJECTS_PROGNAME")) == NULL)
main_local = "";
if ((fmt1 = getenv("LD_TRACE_LOADED_OBJECTS_FMT1")) == NULL)
fmt1 = "\t-l%o.%m => %p (%x)\n";
if ((fmt2 = getenv("LD_TRACE_LOADED_OBJECTS_FMT2")) == NULL)
fmt2 = "\t%o (%x)\n";
for (; smp; smp = smp->som_next) {
struct sod *sodp;
char *name, *path;
if ((sodp = smp->som_sod) == NULL)
continue;
name = (char *)sodp->sod_name;
if (LM_PARENT(smp))
name += (long)LM_LDBASE(LM_PARENT(smp));
if ((path = smp->som_path) == NULL)
path = "not found";
fmt = sodp->sod_library ? fmt1 : fmt2;
while ((c = *fmt++) != '\0') {
switch (c) {
default:
putchar(c);
continue;
case '\\':
switch (c = *fmt) {
case '\0':
continue;
case 'n':
putchar('\n');
break;
case 't':
putchar('\t');
break;
}
break;
case '%':
switch (c = *fmt) {
case '\0':
continue;
case '%':
default:
putchar(c);
break;
case 'A':
printf("%s", main_local);
break;
case 'a':
printf("%s", main_progname);
break;
case 'o':
printf("%s", name);
break;
case 'm':
printf("%d", sodp->sod_major);
break;
case 'n':
printf("%d", sodp->sod_minor);
break;
case 'p':
printf("%s", path);
break;
case 'x':
printf("%p", smp->som_addr);
break;
}
break;
}
++fmt;
}
}
}
/*
* Allocate a new link map and return a pointer to it.
*
* PATH is the pathname of the shared object.
*
* SODP is a pointer to the shared object dependency structure responsible
* for causing the new object to be loaded. PARENT is the shared object
* into which SODP points. Both can be NULL if the new object is not
* being loaded as a result of a shared object dependency.
*
* ADDR is the address at which the object has been mapped. DP is a pointer
* to its _dynamic structure.
*/
static struct so_map *
alloc_link_map(path, sodp, parent, addr, dp)
const char *path;
struct sod *sodp;
struct so_map *parent;
caddr_t addr;
struct _dynamic *dp;
{
struct so_map *smp;
struct somap_private *smpp;
#ifdef DEBUG /* { */
xprintf("alloc_link_map: \"%s\" at %p\n", path, addr);
#endif /* } */
smp = (struct so_map *)xmalloc(sizeof(struct so_map));
smpp = (struct somap_private *)xmalloc(sizeof(struct somap_private));
init_link_map(smp, smpp, path, sodp, parent, addr, dp);
/* Link the new entry into the list of link maps */
smpp->spd_prev = link_map_tail;
if(link_map_tail == NULL) /* First link map entered into list */
link_map_head = link_map_tail = smp;
else { /* Append to end of list */
link_map_tail->som_next = smp;
link_map_tail = smp;
}
return smp;
}
/*
* Initialize a link map entry that has already been allocated.
*/
static void
init_link_map(smp, smpp, path, sodp, parent, addr, dp)
struct so_map *smp;
struct somap_private *smpp;
const char *path;
struct sod *sodp;
struct so_map *parent;
caddr_t addr;
struct _dynamic *dp;
{
memset(smp, 0, sizeof *smp);
memset(smpp, 0, sizeof *smpp);
smp->som_spd = (caddr_t)smpp;
smp->som_addr = addr;
smp->som_path = path ? strdup(path) : NULL;
smp->som_sod = sodp;
smp->som_dynamic = dp;
smpp->spd_parent = parent;
#ifdef SUN_COMPAT
smpp->spd_offset =
(addr==0 && dp && dp->d_version==LD_VERSION_SUN) ? PAGSIZ : 0;
#endif
}
/*
* Remove the specified link map entry from the list of link maps, and free
* the associated storage.
*/
static void
free_link_map(smp)
struct so_map *smp;
{
struct somap_private *smpp = LM_PRIVATE(smp);
#ifdef DEBUG /* { */
xprintf("free_link_map: \"%s\"\n", smp->som_path);
#endif /* } */
if(smpp->spd_prev == NULL) /* Removing first entry in list */
link_map_head = smp->som_next;
else /* Update link of previous entry */
smpp->spd_prev->som_next = smp->som_next;
if(smp->som_next == NULL) /* Removing last entry in list */
link_map_tail = smpp->spd_prev;
else /* Update back link of next entry */
LM_PRIVATE(smp->som_next)->spd_prev = smpp->spd_prev;
if (smp->som_path != NULL)
free(smp->som_path);
free(smpp);
free(smp);
}
/*
* Map the shared object specified by PATH into memory, if it is not
* already mapped. Increment the object's reference count, and return a
* pointer to its link map.
*
* As a special case, if PATH is NULL, it is taken to refer to the main
* program.
*
* SODP is a pointer to the shared object dependency structure that caused
* this object to be requested. PARENT is a pointer to the link map of
* the shared object containing that structure. For a shared object not
* being mapped as a result of a shared object dependency, these pointers
* should be NULL. An example of this is a shared object that is explicitly
* loaded via dlopen().
*
* The return value is a pointer to the link map for the requested object.
* If the operation failed, the return value is NULL. In that case, an
* error message can be retrieved by calling dlerror().
*/
static struct so_map *
map_object(path, sodp, parent)
const char *path;
struct sod *sodp;
struct so_map *parent;
{
struct so_map *smp;
struct stat statbuf;
if(path == NULL) /* Special case for the main program itself */
smp = link_map_head;
else {
/*
* Check whether the shared object is already mapped.
* We check first for an exact match by pathname. That
* will detect the usual case. If no match is found by
* pathname, then stat the file, and check for a match by
* device and inode. That will detect the less common case
* involving multiple links to the same library.
*/
for(smp = link_map_head; smp != NULL; smp = smp->som_next) {
if(!(LM_PRIVATE(smp)->spd_flags & (RTLD_MAIN|RTLD_RTLD))
&& smp->som_path != NULL
&& strcmp(smp->som_path, path) == 0)
break;
}
if(smp == NULL) { /* Check for a match by device and inode */
if (stat(path, &statbuf) == -1) {
generror ("cannot stat \"%s\" : %s",
path, strerror(errno));
return NULL;
}
for (smp = link_map_head; smp != NULL;
smp = smp->som_next) {
struct somap_private *smpp = LM_PRIVATE(smp);
if (!(smpp->spd_flags & (RTLD_MAIN | RTLD_RTLD))
&& smpp->spd_ino == statbuf.st_ino
&& smpp->spd_dev == statbuf.st_dev)
break;
}
}
}
if (smp == NULL) { /* We must map the object */
struct _dynamic *dp;
int fd;
caddr_t addr;
struct exec hdr;
struct somap_private *smpp;
if ((fd = open(path, O_RDONLY, 0)) == -1) {
generror ("open failed for \"%s\" : %s",
path, strerror (errno));
return NULL;
}
if (read(fd, &hdr, sizeof(hdr)) != sizeof(hdr)) {
generror ("header read failed for \"%s\"", path);
(void)close(fd);
return NULL;
}
if (N_BADMAG(hdr)) {
generror ("bad magic number in \"%s\"", path);
(void)close(fd);
return NULL;
}
/*
* Map the entire address space of the object. It is
* tempting to map just the text segment at first, in
* order to avoid having to use mprotect to change the
* protections of the data segment. But that would not
* be correct. Mmap might find a group of free pages
* large enough to hold the text segment, but not large
* enough for the entire object. When we then mapped
* in the data and BSS segments, they would either be
* non-contiguous with the text segment (if we didn't
* specify MAP_FIXED), or they would map over some
* previously mapped region (if we did use MAP_FIXED).
* The only way we can be sure of getting a contigous
* region that is large enough is to map the entire
* region at once.
*/
if ((addr = mmap(0, hdr.a_text + hdr.a_data + hdr.a_bss,
PROT_READ|PROT_EXEC,
MAP_COPY, fd, 0)) == (caddr_t)-1) {
generror ("mmap failed for \"%s\" : %s",
path, strerror (errno));
(void)close(fd);
return NULL;
}
(void)close(fd);
/* Change the data segment to writable */
if (mprotect(addr + hdr.a_text, hdr.a_data,
PROT_READ|PROT_WRITE|PROT_EXEC) != 0) {
generror ("mprotect failed for \"%s\" : %s",
path, strerror (errno));
(void)munmap(addr, hdr.a_text + hdr.a_data + hdr.a_bss);
return NULL;
}
/* Map in pages of zeros for the BSS segment */
if (mmap(addr + hdr.a_text + hdr.a_data, hdr.a_bss,
PROT_READ|PROT_WRITE|PROT_EXEC,
MAP_ANON|MAP_COPY|MAP_FIXED,
anon_fd, 0) == (caddr_t)-1) {
generror ("mmap failed for \"%s\" : %s",
path, strerror (errno));
(void)munmap(addr, hdr.a_text + hdr.a_data + hdr.a_bss);
return NULL;
}
/* Assume _DYNAMIC is the first data item */
dp = (struct _dynamic *)(addr+hdr.a_text);
/* Fixup __DYNAMIC structure */
(long)dp->d_un.d_sdt += (long)addr;
smp = alloc_link_map(path, sodp, parent, addr, dp);
/* save segment sizes for unmap. */
smpp = LM_PRIVATE(smp);
smpp->a_text = hdr.a_text;
smpp->a_data = hdr.a_data;
smpp->a_bss = hdr.a_bss;
/*
* Save the device and inode, so we can detect multiple links
* to the same library. Note, if we reach this point, then
* statbuf is guaranteed to have been filled in.
*/
smpp->spd_dev = statbuf.st_dev;
smpp->spd_ino = statbuf.st_ino;
}
LM_PRIVATE(smp)->spd_refcount++;
if(LM_PRIVATE(smp)->spd_refcount == 1) { /* First use of object */
/*
* Recursively map all of the shared objects that this
* one depends upon.
*/
if(map_sods(smp) == -1) { /* Failed */
unmap_object(smp, 0); /* Clean up */
return NULL;
}
}
return smp;
}
/*
* Map all the shared libraries named in the LD_PRELOAD environment
* variable.
*
* Returns 0 on success, -1 on failure. On failure, an error message can
* be gotten via dlerror().
*/
static int
map_preload __P((void)) {
char *ld_name = ld_preload;
char *name;
while ((name = strsep(&ld_name, ":")) != NULL) {
char *path = NULL;
struct so_map *smp = NULL;
if (*name != '\0') {
path = (strchr(name, '/') != NULL) ? strdup(name) :
rtfindfile(name);
}
if (path == NULL) {
generror("Can't find LD_PRELOAD shared"
" library \"%s\"", name);
} else {
smp = map_object(path, (struct sod *) NULL,
(struct so_map *) NULL);
free(path);
}
if (ld_name != NULL)
*(ld_name - 1) = ':';
if (smp == NULL) {
/*
* We don't bother to unmap already-loaded libraries
* on failure, because in that case the program is
* about to die anyway.
*/
return -1;
}
}
return 0;
}
/*
* Map all of the shared objects that a given object depends upon. PARENT is
* a pointer to the link map for the shared object whose dependencies are
* to be mapped.
*
* Returns 0 on success. Returns -1 on failure. In that case, an error
* message can be retrieved by calling dlerror().
*/
static int
map_sods(parent)
struct so_map *parent;
{
struct somap_private *parpp = LM_PRIVATE(parent);
struct so_list **soltail = &parpp->spd_children;
long next = LD_NEED(parent->som_dynamic);
while(next != 0) {
struct sod *sodp =
(struct sod *) (LM_LDBASE(parent) + next);
char *name =
(char *) (LM_LDBASE(parent) + sodp->sod_name);
char *path = NULL;
struct so_map *smp = NULL;
if(sodp->sod_library) {
/*
* First try for a match with an adequate minor
* number.
*/
path = rtfindlib(name, sodp->sod_major,
sodp->sod_minor, 1);
/*
* If none was found, try for just a major version
* match. A warning is issued by rtfindlib in
* this case, since the minor version number isn't
* really high enough.
*/
if (path == NULL)
path = rtfindlib(name, sodp->sod_major,
sodp->sod_minor, 0);
if(path == NULL && !ld_tracing) {
generror ("Can't find shared library"
" \"lib%s.so.%d.%d\"", name,
sodp->sod_major, sodp->sod_minor);
}
} else {
if(careful && name[0] != '/') {
generror("Shared library path must start"
" with \"/\" for \"%s\"", name);
} else
path = strdup(name);
}
if(path != NULL) {
smp = map_object(path, sodp, parent);
free(path);
}
if(smp != NULL) {
struct so_list *solp = (struct so_list *)
xmalloc(sizeof(struct so_list));
solp->sol_map = smp;
solp->sol_next = NULL;
*soltail = solp;
soltail = &solp->sol_next;
} else if(ld_tracing) {
/*
* Allocate a dummy map entry so that we will get the
* "not found" message.
*/
(void)alloc_link_map(NULL, sodp, parent, 0, 0);
} else if (ld_ignore_missing_objects) {
const char *msg;
/*
* Call __dlerror() even it we're not going to use
* the message, in order to clear the saved message.
*/
msg = __dlerror(); /* Should never be NULL */
if (!ld_suppress_warnings)
warnx("warning: %s", msg);
} else /* Give up */
break;
next = sodp->sod_next;
}
if(next != 0) {
/*
* Oh drat, we have to clean up a mess.
*
* We failed to load a shared object that we depend upon.
* So now we have to unload any dependencies that we had
* already successfully loaded prior to the error.
*
* Cleaning up doesn't matter so much for the initial
* loading of the program, since any failure is going to
* terminate the program anyway. But it is very important
* to clean up properly when something is being loaded
* via dlopen().
*/
struct so_list *solp;
while((solp = parpp->spd_children) != NULL) {
unmap_object(solp->sol_map, 0);
parpp->spd_children = solp->sol_next;
free(solp);
}
return -1;
}
return 0;
}
/*
* Relocate the DAG of shared objects rooted at the given link map
* entry. Returns 0 on success, or -1 on failure. On failure, an
* error message can be retrieved via dlerror().
*/
static int
reloc_dag(root, bind_now)
struct so_map *root;
int bind_now;
{
struct so_map *smp;
/*
* Relocate all newly-loaded objects. We avoid recursion for this
* step by taking advantage of a few facts. This function is called
* only when there are in fact some newly-loaded objects to process.
* Furthermore, all newly-loaded objects will have their link map
* entries at the end of the link map list. And, the root of the
* tree of objects just loaded will have been the first to be loaded
* and therefore the first new object in the link map list. Finally,
* we take advantage of the fact that we can relocate the newly-loaded
* objects in any order.
*
* All these facts conspire to let us simply loop over the tail
* portion of the link map list, relocating each object so
* encountered.
*/
for(smp = root; smp != NULL; smp = smp->som_next) {
if(!(LM_PRIVATE(smp)->spd_flags & RTLD_RTLD)) {
if(reloc_map(smp, bind_now) < 0)
return -1;
}
}
/*
* Copy any relocated initialized data. Again, we can just loop
* over the appropriate portion of the link map list.
*/
for(smp = root; smp != NULL; smp = smp->som_next) {
if(!(LM_PRIVATE(smp)->spd_flags & RTLD_RTLD))
reloc_copy(smp);
}
return 0;
}
/*
* Remove a reference to the shared object specified by SMP. If no
* references remain, unmap the object and, recursively, its descendents.
* This function also takes care of calling the finalization routines for
* objects that are removed.
*
* If KEEP is true, then the actual calls to munmap() are skipped,
* and the object is kept in memory. That is used only for finalization,
* from dlexit(), when the program is exiting. There are two reasons
* for it. First, the program is exiting and there is no point in
* spending the time to explicitly unmap its shared objects. Second,
* even after dlexit() has been called, there are still a couple of
* calls that are made to functions in libc. (This is really a bug
* in crt0.) So libc and the main program, at least, must remain
* mapped in that situation.
*
* Under no reasonable circumstances should this function fail. If
* anything goes wrong, we consider it an internal error, and report
* it with err().
*/
static void
unmap_object(smp, keep)
struct so_map *smp;
int keep;
{
struct somap_private *smpp = LM_PRIVATE(smp);
smpp->spd_refcount--;
if(smpp->spd_refcount == 0) { /* Finished with this object */
struct so_list *solp;
if(smpp->spd_flags & RTLD_INIT) { /* Was initialized */
/*
* Call the object's finalization routine. For
* backward compatibility, we first try to call
* ".fini". If that does not exist, we call
* "__fini".
*/
if(call_map(smp, ".fini") == -1)
call_map(smp, "__fini");
}
/* Recursively unreference the object's descendents */
while((solp = smpp->spd_children) != NULL) {
unmap_object(solp->sol_map, keep);
smpp->spd_children = solp->sol_next;
free(solp);
}
if(!keep) { /* Unmap the object from memory */
if(munmap(smp->som_addr,
smpp->a_text + smpp->a_data + smpp->a_bss) < 0)
err(1, "internal error 1: munmap failed");
/* Unlink and free the object's link map entry */
free_link_map(smp);
}
}
}
static inline int
check_text_reloc(r, smp, addr)
struct relocation_info *r;
struct so_map *smp;
caddr_t addr;
{
char *sym;
if (addr >= LM_ETEXT(smp))
return 0;
if (RELOC_EXTERN_P(r))
sym = LM_STRINGS(smp) +
LM_SYMBOL(smp, RELOC_SYMBOL(r))->nz_strx;
else
sym = "";
if (!ld_suppress_warnings && ld_warn_non_pure_code)
warnx("warning: non pure code in %s at %x (%s)",
smp->som_path, r->r_address, sym);
if (smp->som_write == 0 &&
mprotect(smp->som_addr + LM_TXTADDR(smp),
LD_TEXTSZ(smp->som_dynamic),
PROT_READ|PROT_WRITE|PROT_EXEC) == -1) {
generror ("mprotect failed for \"%s\" : %s",
smp->som_path, strerror (errno));
return -1;
}
smp->som_write = 1;
return 0;
}
static int
reloc_map(smp, bind_now)
struct so_map *smp;
int bind_now;
{
/*
* Caching structure for reducing the number of calls to
* lookup() during relocation.
*
* While relocating a given shared object, the dynamic linker
* maintains a caching vector that is directly indexed by
* the symbol number in the relocation entry. The first time
* a given symbol is looked up, the caching vector is
* filled in with a pointer to the symbol table entry, and
* a pointer to the so_map of the shared object in which the
* symbol was defined. On subsequent uses of the same symbol,
* that information is retrieved directly from the caching
* vector, without calling lookup() again.
*
* A symbol that is referenced in a relocation entry is
* typically referenced in many relocation entries, so this
* caching reduces the number of calls to lookup()
* dramatically. The overall improvement in the speed of
* dynamic linking is also dramatic -- as much as a factor
* of three for programs that use many shared libaries.
*/
struct cacheent {
struct nzlist *np; /* Pointer to symbol entry */
struct so_map *src_map; /* Shared object that defined symbol */
};
struct _dynamic *dp = smp->som_dynamic;
struct relocation_info *r = LM_REL(smp);
struct relocation_info *rend = r + LD_RELSZ(dp)/sizeof(*r);
long symbolbase = (long)LM_SYMBOL(smp, 0);
char *stringbase = LM_STRINGS(smp);
int symsize = LD_VERSION_NZLIST_P(dp->d_version) ?
sizeof(struct nzlist) :
sizeof(struct nlist);
long numsyms = LD_STABSZ(dp) / symsize;
size_t cachebytes = numsyms * sizeof(struct cacheent);
struct cacheent *symcache =
(struct cacheent *) alloca(cachebytes);
if(symcache == NULL) {
generror("Cannot allocate symbol caching vector for %s",
smp->som_path);
return -1;
}
bzero(symcache, cachebytes);
if (LD_PLTSZ(dp))
md_fix_jmpslot(LM_PLT(smp),
(long)LM_PLT(smp), (long)binder_entry);
for (; r < rend; r++) {
char *sym;
caddr_t addr;
/*
* Objects linked with "-Bsymbolic" can end up having unused
* relocation entries at the end. These can be detected by
* the fact that they have an address of 0.
*/
if(r->r_address == 0) /* Finished relocating this object */
break;
addr = smp->som_addr + r->r_address;
if (check_text_reloc(r, smp, addr) < 0)
return -1;
if (RELOC_EXTERN_P(r)) {
struct so_map *src_map = NULL;
struct nzlist *p, *np;
long relocation;
if (RELOC_JMPTAB_P(r) && !bind_now)
continue;
p = (struct nzlist *)
(symbolbase + symsize * RELOC_SYMBOL(r));
if (p->nz_type == (N_SETV + N_EXT))
src_map = smp;
sym = stringbase + p->nz_strx;
/*
* Look up the symbol, checking the caching
* vector first.
*/
np = symcache[RELOC_SYMBOL(r)].np;
if(np != NULL) /* Symbol already cached */
src_map = symcache[RELOC_SYMBOL(r)].src_map;
else { /* Symbol not cached yet */
np = lookup(sym, &src_map, RELOC_JMPTAB_P(r));
/*
* Record the needed information about
* the symbol in the caching vector,
* so that we won't have to call
* lookup the next time we encounter
* the symbol.
*/
symcache[RELOC_SYMBOL(r)].np = np;
symcache[RELOC_SYMBOL(r)].src_map = src_map;
}
if (np == NULL) {
generror ("Undefined symbol \"%s\" in %s:%s",
sym, main_progname, smp->som_path);
return -1;
}
/*
* Found symbol definition.
* If it's in a link map, adjust value
* according to the load address of that map.
* Otherwise it's a run-time allocated common
* whose value is already up-to-date.
*/
relocation = np->nz_value;
if (src_map)
relocation += (long)src_map->som_addr;
if (RELOC_JMPTAB_P(r)) {
md_bind_jmpslot(relocation, addr);
continue;
}
relocation += md_get_addend(r, addr);
if (RELOC_PCREL_P(r))
relocation -= (long)smp->som_addr;
if (RELOC_COPY_P(r) && src_map) {
(void)enter_rts(sym, sym_hash(sym),
(long)addr,
N_DATA + N_EXT,
src_map->som_addr + np->nz_value,
np->nz_size, src_map);
continue;
}
md_relocate(r, relocation, addr, 0);
} else {
md_relocate(r,
#ifdef SUN_COMPAT
md_get_rt_segment_addend(r, addr)
#else
md_get_addend(r, addr)
#endif
+ (long)smp->som_addr, addr, 0);
}
}
if (smp->som_write) {
if (mprotect(smp->som_addr + LM_TXTADDR(smp),
LD_TEXTSZ(smp->som_dynamic),
PROT_READ|PROT_EXEC) == -1) {
generror ("mprotect failed for \"%s\" : %s",
smp->som_path, strerror (errno));
return -1;
}
smp->som_write = 0;
}
return 0;
}
static void
reloc_copy(smp)
struct so_map *smp;
{
struct rt_symbol *rtsp;
for (rtsp = rt_symbol_head; rtsp; rtsp = rtsp->rt_next)
if ((rtsp->rt_smp == NULL || rtsp->rt_smp == smp) &&
rtsp->rt_sp->nz_type == N_DATA + N_EXT) {
bcopy(rtsp->rt_srcaddr, (caddr_t)rtsp->rt_sp->nz_value,
rtsp->rt_sp->nz_size);
}
}
/*
* Initialize the DAG of shared objects rooted at the given object.
*/
static void
init_dag(smp)
struct so_map *smp;
{
struct somap_private *smpp = LM_PRIVATE(smp);
if(!(smpp->spd_flags & RTLD_INIT)) { /* Not initialized yet */
smpp->spd_flags |= RTLD_INIT;
/* Make sure all the children are initialized */
if(smpp->spd_children != NULL)
init_sods(smpp->spd_children);
if(call_map(smp, ".init") == -1)
call_map(smp, "__init");
}
}
static void
init_sods(solp)
struct so_list *solp;
{
/* Recursively initialize the rest of the list */
if(solp->sol_next != NULL)
init_sods(solp->sol_next);
/* Initialize the first element of the list */
init_dag(solp->sol_map);
}
/*
* Call a function in a given shared object. SMP is the shared object, and
* SYM is the name of the function.
*
* Returns 0 on success, or -1 if the symbol was not found. Failure is not
* necessarily an error condition, so no error message is generated.
*/
static int
call_map(smp, sym)
struct so_map *smp;
char *sym;
{
struct so_map *src_map = smp;
struct nzlist *np;
np = lookup(sym, &src_map, 1);
if (np) {
(*(void (*)())(src_map->som_addr + np->nz_value))();
return 0;
}
return -1;
}
/*
* Run-time common symbol table.
*/
#define RTC_TABSIZE 57
static struct rt_symbol *rt_symtab[RTC_TABSIZE];
/*
* Look up a symbol in the run-time common symbol table. For efficiency,
* the symbol's hash value must be passed in too.
*/
static inline struct rt_symbol *
lookup_rts(name, hash)
char *name;
unsigned long hash;
{
register struct rt_symbol *rtsp;
for (rtsp = rt_symtab[hash % RTC_TABSIZE]; rtsp; rtsp = rtsp->rt_link)
if (strcmp(name, rtsp->rt_sp->nz_name) == 0)
return rtsp;
return NULL;
}
/*
* Enter a symbol into the run-time common symbol table. For efficiency,
* the symbol's hash value must be passed in too.
*/
static struct rt_symbol *
enter_rts(name, hash, value, type, srcaddr, size, smp)
char *name;
unsigned long hash;
long value;
int type;
caddr_t srcaddr;
long size;
struct so_map *smp;
{
register struct rt_symbol *rtsp, **rpp;
/* Find end of bucket */
for (rpp = &rt_symtab[hash % RTC_TABSIZE]; *rpp; rpp = &(*rpp)->rt_link)
continue;
/* Allocate new common symbol */
rtsp = (struct rt_symbol *)xmalloc(sizeof(struct rt_symbol));
rtsp->rt_sp = (struct nzlist *)xmalloc(sizeof(struct nzlist));
rtsp->rt_sp->nz_name = strdup(name);
rtsp->rt_sp->nz_value = value;
rtsp->rt_sp->nz_type = type;
rtsp->rt_sp->nz_size = size;
rtsp->rt_srcaddr = srcaddr;
rtsp->rt_smp = smp;
rtsp->rt_link = NULL;
/* Link onto linear list as well */
rtsp->rt_next = rt_symbol_head;
rt_symbol_head = rtsp;
*rpp = rtsp;
return rtsp;
}
/*
* Lookup NAME in the link maps. The link map producing a definition
* is returned in SRC_MAP. If SRC_MAP is not NULL on entry the search
* is confined to that map.
*
* REAL_DEF_ONLY is a boolean which specifies whether certain special
* symbols for functions should satisfy the lookup or not. The
* reasons behind it are somewhat complicated. They are motivated
* by the scenario in which the address of a single function is
* taken from several shared objects. The address should come out
* the same in all cases, because the application code might decide
* to use it in comparisons. To make this work, the linker creates
* a symbol entry for the function in the main executable, with a
* type of N_UNDF+N_EXT, an N_AUX of AUX_FUNC, and a value that
* refers to the PLT entry for the function in the main executable.
* If REAL_DEF_ONLY is false, then this kind of special symbol is
* considered a "definition" when lookup up the symbol. Since the
* main executable is at the beginning of the shared object search
* list, the result is that references from all shared objects will
* resolve to the main program's PLT entry, and thus the function
* addresses will compare equal as they should.
*
* When relocating the PLT entry itself, we obviously must match
* only the true defining symbol for the function. In that case, we
* set REAL_DEF_ONLY to true, which disables matching the special
* N_UNDF+N_EXT entries.
*
* It is not so clear how to set this flag for a lookup done from
* dlsym. If the lookup specifies a particular shared object other
* than the main executable, the flag makes no difference -- only the
* true definition will be matched. (That is because the special
* symbols are only present in the main executable, which will not
* be searched.) But when the lookup is over all the shared objects
* (i.e., dlsym's "fd" parameter is NULL), then the flag does have an
* effect. We elect to match only the true definition even in that
* case.
*
* The upshot of all this is the following rule of thumb: Set
* REAL_DEF_ONLY in all cases except when processing a non-PLT
* relocation.
*/
static struct nzlist *
lookup(name, src_map, real_def_only)
char *name;
struct so_map **src_map; /* IN/OUT */
int real_def_only;
{
unsigned long hash;
hash = sym_hash(name);
if (*src_map != NULL) /* Look in just one specific object */
return lookup_in_obj(name, hash, *src_map, real_def_only);
else { /* Search runtime symbols and all loaded objects */
unsigned long common_size;
struct so_map *smp;
struct rt_symbol *rtsp;
struct nzlist *np;
if ((rtsp = lookup_rts(name, hash)) != NULL)
return rtsp->rt_sp;
common_size = 0;
for (smp = link_map_head; smp; smp = smp->som_next) {
if (LM_PRIVATE(smp)->spd_flags & RTLD_RTLD)
continue;
np = lookup_in_obj(name, hash, smp, real_def_only);
if (np == NULL)
continue;
/* We know that np->nz_value > 0 at this point. */
if (np->nz_type == N_UNDF+N_EXT &&
N_AUX(&np->nlist) != AUX_FUNC) { /* Common */
if (common_size < np->nz_value)
common_size = np->nz_value;
continue;
}
/* We found the symbol definition. */
*src_map = smp;
return np;
}
if (common_size > 0) { /* It is a common symbol. */
void *mem;
mem = memset(xmalloc(common_size), 0, common_size);
rtsp = enter_rts(name, hash, (long)mem, N_UNDF + N_EXT,
0, common_size, NULL);
return rtsp->rt_sp;
}
/*
* Just before giving up, check for the __error() hack.
*/
np = lookup_errno_hack(name, src_map, real_def_only);
if (np != NULL)
return np;
/* No definition was found for the symbol. */
return NULL;
}
}
/*
* Lookup a symbol in one specific shared object. The hash
* value is passed in for efficiency. For an explanation of the
* "real_def_only" flag, see the comment preceding the "lookup"
* function.
*/
static struct nzlist *
lookup_in_obj(name, hash, smp, real_def_only)
char *name;
unsigned long hash;
struct so_map *smp;
int real_def_only;
{
unsigned long buckets;
struct rrs_hash *hp;
char *cp;
struct nzlist *np;
char *symbolbase;
struct rrs_hash *hashbase;
char *stringbase;
size_t symsize;
if ((buckets = LD_BUCKETS(smp->som_dynamic)) == 0)
return NULL;
hashbase = LM_HASH(smp);
restart:
hp = &hashbase[hash % buckets];
if (hp->rh_symbolnum == -1)
return NULL;
symbolbase = (char *)LM_SYMBOL(smp, 0);
stringbase = LM_STRINGS(smp);
symsize = LD_VERSION_NZLIST_P(smp->som_dynamic->d_version)?
sizeof(struct nzlist) : sizeof(struct nlist);
for ( ; ; ) {
np = (struct nzlist *)(symbolbase + hp->rh_symbolnum*symsize);
cp = stringbase + np->nz_strx;
if (strcmp(cp, name) == 0)
break;
if (hp->rh_next == 0) /* End of hash chain */
return NULL;
hp = hashbase + hp->rh_next;
}
/*
* We have a symbol with the name we're looking for.
*/
if (np->nz_type == N_INDR+N_EXT) {
/*
* Next symbol gives the aliased name. Restart
* search with new name.
*/
name = stringbase + (++np)->nz_strx;
hash = sym_hash(name);
goto restart;
}
if (np->nz_value == 0) /* It's not a definition */
return NULL;
if (real_def_only) /* Don't match special function symbols. */
if (np->nz_type == N_UNDF+N_EXT &&
N_AUX(&np->nlist) == AUX_FUNC)
return NULL;
return np;
}
/*
* Return the value of a symbol in the user's program. This is used
* internally for a few symbols which must exist. If the requested
* symbol is not found, this simply exits with a fatal error.
*/
static void *
sym_addr(name)
char *name;
{
struct so_map *smp;
struct nzlist *np;
smp = NULL;
np = lookup(name, &smp, 1);
if (np == NULL)
errx(1, "Program has no symbol \"%s\"", name);
return ((smp == NULL) ? NULL : smp->som_addr) + np->nz_value;
}
static int *p_errno; /* Pointer to errno variable in main program. */
/*
* Help old a.out binaries that are broken by the new errno macro. They
* can be missing __error() through no fault of their own. In particular,
* old a.out binaries can link against an old libc that does not contain
* __error(), yet still require __error() because of other libraries that
* have been recompiled since the errno change. This locates the backward
* compatible work-alike we have hidden here in ld.so.
*/
static struct nzlist *
lookup_errno_hack(sym, src_map, real_def_only)
char *sym;
struct so_map **src_map;
int real_def_only;
{
struct so_map *smp;
struct nzlist *np;
if (strcmp(sym, "___error") != 0)
return NULL;
/*
* Locate errno in the main program. If it's not there, NULL
* will be returned by our __error() substitute, and a core dump
* will follow. That's impossible, of course, since crt0.o always
* supplies errno.
*/
smp = NULL;
np = lookup("_errno", &smp, 1);
if (np != NULL && smp != NULL) {
p_errno = (int *)(smp->som_addr + np->nz_value);
#ifdef DEBUG
xprintf(" HACK: _errno at %p in %s\n", p_errno, smp->som_path);
#endif
}
/*
* Specifically find the ld.so link map because most routines
* skip over it during normal operation.
*/
for (smp = link_map_head; ; smp = smp->som_next)
if (LM_PRIVATE(smp)->spd_flags & RTLD_RTLD)
break;
/*
* Find our __error() substitute stashed here in ld.so.
*/
np = lookup("___error_unthreaded_hack", &smp, real_def_only);
if (np != NULL)
*src_map = smp;
#ifdef DEBUG
if (np == NULL)
xprintf(" HACK: %s fudge not found, oops\n", sym);
else
xprintf(" HACK: %s fudge in %s\n", sym, smp->som_path);
#endif
return np;
}
/*
* Just like __error_unthreaded(), but for those poor orphaned a.out
* binaries from way back that are bamboozled by the new errno macro.
*/
int *
__error_unthreaded_hack()
{
return p_errno;
}
/*
* This routine is called from the jumptable to resolve
* procedure calls to shared objects.
*/
long
binder(jsp)
jmpslot_t *jsp;
{
struct so_map *smp, *src_map = NULL;
long addr;
char *sym;
struct nzlist *np;
int index;
/*
* Find the PLT map that contains JSP.
*/
for (smp = link_map_head; smp; smp = smp->som_next) {
if (LM_PLT(smp) < jsp &&
jsp < LM_PLT(smp) + LD_PLTSZ(smp->som_dynamic)/sizeof(*jsp))
break;
}
if (smp == NULL)
errx(1, "Call to binder from unknown location: %p\n", jsp);
index = jsp->reloc_index & JMPSLOT_RELOC_MASK;
/* Get the local symbol this jmpslot refers to */
sym = LM_STRINGS(smp) +
LM_SYMBOL(smp,RELOC_SYMBOL(&LM_REL(smp)[index]))->nz_strx;
np = lookup(sym, &src_map, 1);
if (np == NULL)
errx(1, "Undefined symbol \"%s\" called from %s:%s at %p",
sym, main_progname, smp->som_path, jsp);
/* Fixup jmpslot so future calls transfer directly to target */
addr = np->nz_value;
if (src_map)
addr += (long)src_map->som_addr;
md_fix_jmpslot(jsp, (long)jsp, addr);
#if DEBUG
xprintf(" BINDER: %s located at = %#x in %s\n", sym, addr,
src_map->som_path);
#endif
return addr;
}
static struct hints_header *hheader; /* NULL means not mapped */
static struct hints_bucket *hbuckets;
static char *hstrtab;
/*
* Map the hints file into memory, if it is not already mapped. Returns
* 0 on success, or -1 on failure.
*/
static int
maphints __P((void))
{
static int hints_bad; /* TRUE if hints are unusable */
static int paths_added;
int hfd;
struct hints_header hdr;
caddr_t addr;
if (hheader != NULL) /* Already mapped */
return 0;
if (hints_bad) /* Known to be corrupt or unavailable */
return -1;
if ((hfd = open(_PATH_LD_HINTS, O_RDONLY, 0)) == -1) {
hints_bad = 1;
return -1;
}
/* Read the header and check it */
if (read(hfd, &hdr, sizeof hdr) != sizeof hdr ||
HH_BADMAG(hdr) ||
(hdr.hh_version != LD_HINTS_VERSION_1 &&
hdr.hh_version != LD_HINTS_VERSION_2)) {
close(hfd);
hints_bad = 1;
return -1;
}
/* Map the hints into memory */
addr = mmap(0, hdr.hh_ehints, PROT_READ, MAP_SHARED, hfd, 0);
if (addr == (caddr_t)-1) {
close(hfd);
hints_bad = 1;
return -1;
}
close(hfd);
hheader = (struct hints_header *)addr;
hbuckets = (struct hints_bucket *)(addr + hheader->hh_hashtab);
hstrtab = (char *)(addr + hheader->hh_strtab);
/* pluck out the system ldconfig path */
if (hheader->hh_version >= LD_HINTS_VERSION_2 && !paths_added) {
add_search_path(hstrtab + hheader->hh_dirlist);
paths_added = 1;
}
return 0;
}
/*
* Unmap the hints file, if it is currently mapped.
*/
static void
unmaphints()
{
if (hheader != NULL) {
munmap((caddr_t)hheader, hheader->hh_ehints);
hheader = NULL;
}
}
int
hinthash(cp, vmajor)
char *cp;
int vmajor;
{
int k = 0;
while (*cp)
k = (((k << 1) + (k >> 14)) ^ (*cp++)) & 0x3fff;
k = (((k << 1) + (k >> 14)) ^ (vmajor*257)) & 0x3fff;
return k;
}
#undef major
#undef minor
/*
* Search for a library in the hints generated by ldconfig. On success,
* returns the full pathname of the matching library. This string is
* always dynamically allocated on the heap.
*
* MINORP is an in/out parameter. If the incoming value of *MINORP is
* >= 0, then no library will be considered a match unless its minor
* version number is at least that large. Otherwise, only the major
* version number is checked. In any case, the minor number of the
* matching library is stored into *MINORP.
*
* Returns NULL if the library cannot be found.
*/
static char *
findhint(name, major, minorp)
char *name;
int major;
int *minorp;
{
struct hints_bucket *bp =
hbuckets + (hinthash(name, major) % hheader->hh_nbucket);
while (1) {
/* Sanity check */
if (bp->hi_namex >= hheader->hh_strtab_sz) {
warnx("Bad name index: %#x\n", bp->hi_namex);
break;
}
if (bp->hi_pathx >= hheader->hh_strtab_sz) {
warnx("Bad path index: %#x\n", bp->hi_pathx);
break;
}
/*
* For a given major number, the hints file has only one
* entry -- namely, the one with the highest minor number.
* If we find an entry with a matching major number, we
* know it is the best one.
*/
if (strcmp(name, hstrtab + bp->hi_namex) == 0 &&
bp->hi_major == major) {
struct stat s;
int realminor;
realminor = bp->hi_ndewey >= 2 ? bp->hi_minor : 0;
if (realminor < *minorp) /* Not good enough */
return NULL;
if (stat(hstrtab + bp->hi_pathx, &s) == -1)
return NULL; /* Doesn't actually exist */
*minorp = realminor;
return strdup(hstrtab + bp->hi_pathx);
}
if (bp->hi_next == -1)
break;
/* Move on to next in bucket */
bp = &hbuckets[bp->hi_next];
}
/* No hints available for name */
return NULL;
}
/*
* Search for the given shared library. On success, returns a string
* containing the full pathname for the library. This string is always
* dynamically allocated on the heap.
*
* Returns NULL if the library cannot be found.
*/
static char *
rtfindlib(name, major, minor, strictminor)
char *name;
int major, minor;
int strictminor;
{
char *ld_path = ld_library_path;
char *path = NULL;
int realminor;
realminor = strictminor ? minor : -1;
if (ld_path != NULL) { /* First, search the directories in ld_path */
/*
* There is no point in trying to use the hints file for this.
*/
char *dir;
while (path == NULL && (dir = strsep(&ld_path, ":")) != NULL) {
path = search_lib_dir(dir, name, &major, &realminor, 0);
if (ld_path != NULL)
*(ld_path - 1) = ':';
}
}
if (path == NULL && maphints() == 0) /* Search the hints file */
path = findhint(name, major, &realminor);
if (path == NULL) /* Search the standard directories */
path = findshlib(name, &major, &realminor, 0);
if (path != NULL && realminor < minor && !ld_suppress_warnings) {
warnx("warning: %s: minor version %d"
" older than expected %d, using it anyway",
path, realminor, minor);
}
return path;
}
/*
* Search for the given shared library file. This is similar to rtfindlib,
* except that the argument is the actual name of the desired library file.
* Thus there is no need to worry about version numbers. The return value
* is a string containing the full pathname for the library. This string
* is always dynamically allocated on the heap.
*
* Returns NULL if the library cannot be found.
*/
static char *
rtfindfile(name)
const char *name;
{
char *ld_path = ld_library_path;
char *path = NULL;
if (ld_path != NULL) { /* First, search the directories in ld_path */
char *dir;
while (path == NULL && (dir = strsep(&ld_path, ":")) != NULL) {
struct stat sb;
path = concat(dir, "/", name);
if (lstat(path, &sb) == -1) { /* Does not exist */
free(path);
path = NULL;
}
if (ld_path != NULL)
*(ld_path - 1) = ':';
}
}
/*
* We don't search the hints file. It is organized around major
* and minor version numbers, so it is not suitable for finding
* a specific file name.
*/
if (path == NULL) /* Search the standard directories */
path = find_lib_file(name);
return path;
}
/*
* Buffer for error messages and a pointer that is set to point to the buffer
* when a error occurs. It acts as a last error flag, being set to NULL
* after an error is returned.
*/
#define DLERROR_BUF_SIZE 512
static char dlerror_buf [DLERROR_BUF_SIZE];
static char *dlerror_msg = NULL;
static void *
__dlopen(path, mode)
const char *path;
int mode;
{
struct so_map *old_tail = link_map_tail;
struct so_map *smp;
int bind_now = mode == RTLD_NOW;
char *name;
/*
* path == NULL is handled by map_object()
*/
anon_open();
name = (path && strchr(path, '/') == NULL) ? rtfindfile(path) : (char *)path;
/* Map the object, and the objects on which it depends */
smp = map_object(name, (struct sod *) NULL, (struct so_map *) NULL);
if (name != path)
free(name);
if(smp == NULL) /* Failed */
return NULL;
LM_PRIVATE(smp)->spd_flags |= RTLD_DL;
/* Relocate and initialize all newly-mapped objects */
if(link_map_tail != old_tail) { /* We have mapped some new objects */
if(reloc_dag(smp, bind_now) == -1) /* Failed */
return NULL;
init_dag(smp);
}
unmaphints();
anon_close();
return smp;
}
static int
__dlclose(fd)
void *fd;
{
struct so_map *smp = (struct so_map *)fd;
struct so_map *scanp;
#ifdef DEBUG
xprintf("dlclose(%s): refcount = %d\n", smp->som_path,
LM_PRIVATE(smp)->spd_refcount);
#endif
/* Check the argument for validity */
for(scanp = link_map_head; scanp != NULL; scanp = scanp->som_next)
if(scanp == smp) /* We found the map in the list */
break;
if(scanp == NULL || !(LM_PRIVATE(smp)->spd_flags & RTLD_DL)) {
generror("Invalid argument to dlclose");
return -1;
}
unmap_object(smp, 0);
return 0;
}
/*
* This form of dlsym is obsolete. Current versions of crt0 don't call
* it. It can still be called by old executables that were linked with
* old versions of crt0.
*/
static void *
__dlsym(fd, sym)
void *fd;
const char *sym;
{
if (fd == RTLD_NEXT) {
generror("RTLD_NEXT not supported by this version of"
" crt0.o");
return NULL;
}
return __dlsym3(fd, sym, NULL);
}
static void *
resolvesym(fd, sym, retaddr)
void *fd;
char *sym;
void *retaddr;
{
struct so_map *smp;
struct so_map *src_map;
struct nzlist *np;
long addr;
if (fd == RTLD_NEXT) {
/* Find the shared object that contains the caller. */
for (smp = link_map_head; smp != NULL; smp = smp->som_next) {
void *textbase = smp->som_addr + LM_TXTADDR(smp);
void *textlimit = LM_ETEXT(smp);
if (textbase <= retaddr && retaddr < textlimit)
break;
}
if (smp == NULL) {
generror("Cannot determine caller's shared object");
return NULL;
}
smp = smp->som_next;
if (smp != NULL && LM_PRIVATE(smp)->spd_flags & RTLD_RTLD)
smp = smp->som_next;
if (smp == NULL) {
generror("No next shared object for RTLD_NEXT");
return NULL;
}
do {
src_map = smp;
np = lookup(sym, &src_map, 1);
} while (np == NULL && (smp = smp->som_next) != NULL);
} else {
smp = (struct so_map *)fd;
src_map = NULL;
/*
* Restrict search to passed map if dlopen()ed.
*/
if (smp != NULL && LM_PRIVATE(smp)->spd_flags & RTLD_DL)
src_map = smp;
np = lookup(sym, &src_map, 1);
}
if (np == NULL) {
generror("Undefined symbol");
return NULL;
}
addr = np->nz_value;
if (src_map)
addr += (long)src_map->som_addr;
return (void *)addr;
}
static int
__dladdr(addr, dlip)
const void *addr;
Dl_info *dlip;
{
struct _dynamic *dp;
struct so_map *smp;
char *stringbase;
long numsyms;
int symsize;
int i;
/* Find the shared object that contains the address. */
for (smp = link_map_head; smp != NULL; smp = smp->som_next) {
struct so_map *src_map;
struct somap_private *smpp;
struct nzlist *np;
smpp = LM_PRIVATE(smp);
if (smpp->spd_flags & RTLD_RTLD)
continue;
if ((void *)smp->som_addr > addr)
continue;
src_map = smp;
if ((np = lookup(END_SYM, &src_map, 1)) == NULL)
continue; /* No "_end" symbol?! */
if (addr < (void *)(smp->som_addr + np->nz_value))
break;
}
if (smp == NULL) {
generror("No shared object contains address");
return 0;
}
dlip->dli_fname = smp->som_path;
dlip->dli_fbase = smp->som_addr;
dlip->dli_saddr = (void *) 0;
dlip->dli_sname = NULL;
dp = smp->som_dynamic;
symsize = LD_VERSION_NZLIST_P(dp->d_version) ?
sizeof(struct nzlist) : sizeof(struct nlist);
numsyms = LD_STABSZ(dp) / symsize;
stringbase = LM_STRINGS(smp);
for (i = 0; i < numsyms; i++) {
struct nzlist *symp = LM_SYMBOL(smp, i);
unsigned long value;
/* Reject all except definitions. */
if (symp->nz_type != N_EXT + N_ABS &&
symp->nz_type != N_EXT + N_TEXT &&
symp->nz_type != N_EXT + N_DATA &&
symp->nz_type != N_EXT + N_BSS)
continue;
/*
* If the symbol is greater than the specified address, or
* if it is further away from addr than the current nearest
* symbol, then reject it.
*/
value = (unsigned long) (smp->som_addr + symp->nz_value);
if (value > (unsigned long) addr ||
value < (unsigned long) dlip->dli_saddr)
continue;
/* Update our idea of the nearest symbol. */
dlip->dli_sname = stringbase + symp->nz_strx;
dlip->dli_saddr = (void *) value;
if (dlip->dli_saddr == addr) /* Can't get any closer. */
break;
}
/*
* Remove any leading underscore from the symbol name, to hide
* our a.out-ness.
*/
if (dlip->dli_sname != NULL && dlip->dli_sname[0] == '_')
dlip->dli_sname++;
return 1;
}
static void *
__dlsym3(fd, sym, retaddr)
void *fd;
const char *sym;
void *retaddr;
{
void *result;
result = resolvesym(fd, sym, retaddr);
/*
* XXX - Ugly, but it makes the least impact on the run-time loader
* sources. We assume that most of the time the error is a
* undefined symbol error from above, so we try again. If it's
* not an undefined symbol we end up getting the same error twice,
* but that's acceptable.
*/
if (result == NULL) {
/* Prepend an underscore and try again */
char *newsym = xmalloc(strlen(sym) + 2);
newsym[0] = '_';
strcpy(&newsym[1], sym);
result = resolvesym(fd, newsym, retaddr);
free(newsym);
}
return result;
}
static const char *
__dlerror __P((void))
{
const char *err;
err = dlerror_msg;
dlerror_msg = NULL; /* Next call will return NULL */
return err;
}
static void
__dlexit __P((void))
{
#ifdef DEBUG
xprintf("__dlexit called\n");
#endif
unmap_object(link_map_head, 1);
}
/*
* Print the current error message and exit with failure status.
*/
static void
die __P((void))
{
const char *msg;
fprintf(stderr, "ld.so failed");
if ((msg = __dlerror()) != NULL)
fprintf(stderr, ": %s", msg);
putc('\n', stderr);
_exit(1);
}
/*
* Generate an error message that can be later be retrieved via dlerror.
*/
static void
generror(char *fmt, ...)
{
va_list ap;
va_start(ap, fmt);
vsnprintf (dlerror_buf, DLERROR_BUF_SIZE, fmt, ap);
dlerror_msg = dlerror_buf;
va_end(ap);
}
void
xprintf(char *fmt, ...)
{
char buf[256];
va_list ap;
va_start(ap, fmt);
vsnprintf(buf, sizeof(buf), fmt, ap);
(void)write(STDOUT_FILENO, buf, strlen(buf));
va_end(ap);
}
/*
* rt_readenv() etc.
*
* Do a sweep over the environment once only, pick up what
* looks interesting.
*
* This is pretty obscure, but is relatively simple. Simply
* look at each environment variable, if it starts with "LD_" then
* look closer at it. If it's in our table, set the variable
* listed. effectively, this is like:
* ld_preload = careful ? NULL : getenv("LD_PRELOAD");
* except that the environment is scanned once only to pick up all
* known variables, rather than scanned multiple times for each
* variable.
*
* If an environment variable of interest is set to the empty string, we
* treat it as if it were unset.
*/
#define L(n, u, v) { n, sizeof(n) - 1, u, v },
struct env_scan_tab {
char *name;
int len;
int unsafe;
char **value;
} scan_tab[] = {
L("LD_LIBRARY_PATH=", 1, &ld_library_path)
L("LD_PRELOAD=", 1, &ld_preload)
L("LD_IGNORE_MISSING_OBJECTS=", 1, &ld_ignore_missing_objects)
L("LD_TRACE_LOADED_OBJECTS=", 0, &ld_tracing)
L("LD_BIND_NOW=", 0, &ld_bind_now)
L("LD_SUPPRESS_WARNINGS=", 0, &ld_suppress_warnings)
L("LD_WARN_NON_PURE_CODE=", 0, &ld_warn_non_pure_code)
{ NULL, 0, 0, NULL }
};
#undef L
static void
rt_readenv()
{
char **p = environ;
char *v;
struct env_scan_tab *t;
/* for each string in the environment... */
while ((v = *p++)) {
/* check for LD_xxx */
if (v[0] != 'L' || v[1] != 'D' || v[2] != '_')
continue;
for (t = scan_tab; t->name; t++) {
if (careful && t->unsafe)
continue; /* skip for set[ug]id */
if (strncmp(t->name, v, t->len) == 0) {
if (*(v + t->len) != '\0') /* Not empty */
*t->value = v + t->len;
break;
}
}
}
}
/*
* Malloc implementation for use within the dynamic linker. At first
* we do a simple allocation using sbrk. After the user's program
* has been loaded, we switch to using whatever malloc functions are
* defined there.
*/
/* Symbols related to the sbrk and brk implementations. */
#define CURBRK_SYM "curbrk"
#define MINBRK_SYM "minbrk"
#define END_SYM "_end"
/* Symbols related to malloc. */
#define FREE_SYM "_free"
#define MALLOC_SYM "_malloc"
#define REALLOC_SYM "_realloc"
/* Hooks into the implementation of sbrk and brk. */
extern char *curbrk __asm__(CURBRK_SYM);
extern char *minbrk __asm__(MINBRK_SYM);
/* Pointers to the user program's malloc functions. */
static void *(*p_malloc) __P((size_t));
static void *(*p_realloc) __P((void *, size_t));
static void (*p_free) __P((void *));
/* Upper limit of the memory allocated by our internal malloc. */
static char *rtld_alloc_lev;
/*
* Set up the internal malloc so that it will take its memory from the
* main program's sbrk arena.
*/
static void
init_internal_malloc __P((void))
{
const struct exec *hdr;
/*
* Before anything calls sbrk or brk, we have to initialize
* its idea of the current break level to just beyond the main
* program's address space. Strictly speaking, the right
* way to do that is to look up the value of "_end" in the
* application's run time symbol table.
*
* That is what we used to do, and it works correctly for
* every valid program. Unfortunately, it doesn't work right
* for "unexec"ed versions of emacs. They are incorrectly
* generated with a wrong value for "_end". (xemacs gets it
* right.)
*
* To work around this, we peek at the exec header to get the
* sizes of the text, data, and bss segments. Luckily, the
* header is in memory at the start of the first mapped page.
* From the segment sizes, we can calculate a proper initial
* value for the break level.
*/
hdr = (const struct exec *)PAGSIZ;
if (N_BADMAG(*hdr)) /* Sanity check */
errx(1, "Cannot find program's a.out header");
rtld_alloc_lev = curbrk = minbrk =
(char *)hdr + hdr->a_text + hdr->a_data + hdr->a_bss;
}
/*
* Set things up so that the dynamic linker can use the program's
* malloc functions.
*/
static void
init_external_malloc __P((void))
{
/*
* Patch the program's idea of the current break address to
* what it really is as a result of the allocations we have
* already done.
*/
*(char **)(sym_addr(CURBRK_SYM)) = curbrk;
/*
* Set the minimum break level too. Otherwise, "unexec"ed
* emacs sets the break too low and wipes out our tables of
* shared objects.
*/
*(char **)(sym_addr(MINBRK_SYM)) = curbrk;
/*
* Set up pointers to the program's allocation functions, so
* that we can use them from now on.
*/
p_malloc = (void *(*)(size_t))(sym_addr(MALLOC_SYM));
p_free = (void (*)(void *))(sym_addr(FREE_SYM));
p_realloc = (void *(*)(void *, size_t))(sym_addr(REALLOC_SYM));
}
void *
malloc(size)
size_t size;
{
char *p;
/* If we are far enough along, we can use the system malloc. */
if (p_malloc != NULL)
return (*p_malloc)(size);
/*
* Otherwise we use our simple built-in malloc. We get the
* memory from brk() in increments of one page. We store the
* allocated size in the first word, so that realloc can be
* made to work.
*/
if (rtld_alloc_lev == NULL)
errx(1, "Internal error: internal malloc called before"
" being initialized");
p = (char *)ALIGN(rtld_alloc_lev);
rtld_alloc_lev = p + sizeof(size_t) + size;
if (rtld_alloc_lev > curbrk) { /* Get memory from system */
char *newbrk;
newbrk = (char *)
roundup2((unsigned long)rtld_alloc_lev, PAGSIZ);
if (brk(newbrk) == -1)
return NULL;
}
*(size_t *)p = size;
return p + sizeof(size_t);
}
void *
realloc(ptr, size)
void *ptr;
size_t size;
{
size_t old_size;
void *new_ptr;
if (ptr == NULL)
return malloc(size);
/*
* If we are far enough along, and if the memory originally came
* from the system malloc, we can use the system realloc.
*/
if (p_realloc != NULL && (char *)ptr >= rtld_alloc_lev)
return (*p_realloc)(ptr, size);
old_size = *((size_t *)ptr - 1);
if (old_size >= size) /* Not expanding the region */
return ptr;
new_ptr = malloc(size);
if (new_ptr != NULL)
memcpy(new_ptr, ptr, old_size);
return new_ptr;
}
void
free(ptr)
void *ptr;
{
if (ptr == NULL)
return;
/*
* If we are far enough along, and if the memory originally came
* from the system malloc, we can use the system free. Otherwise
* we can't free the memory and we just let it go to waste.
*/
if (p_free != NULL && (char *)ptr >= rtld_alloc_lev)
(*p_free)(ptr);
}