freebsd-skq/libexec/rtld-aout/rtld.c

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/*
* 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
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*
* 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.
*
* $FreeBSD$
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*/
#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>
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#include <sys/mman.h>
#ifndef MAP_COPY
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#define MAP_COPY MAP_PRIVATE
#endif
#include <dlfcn.h>
#include <err.h>
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#include <fcntl.h>
#include <a.out.h>
#include <stab.h>
#include <stdio.h>
#include <stdlib.h>
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#include <string.h>
#include <unistd.h>
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#if __STDC__
#include <stdarg.h>
#else
#include <varargs.h>
#endif
#include <link.h>
#include "md.h"
#include "shlib.h"
#include "support.h"
#include "dynamic.h"
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#ifndef MAP_ANON
#define MAP_ANON 0
#define anon_open() do { \
if ((anon_fd = open("/dev/zero", O_RDWR, 0)) == -1) \
err("open: %s", "/dev/zero"); \
} while (0)
#define anon_close() do { \
(void)close(anon_fd); \
anon_fd = -1; \
} while (0)
#else
#define anon_open()
#define anon_close()
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#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 */
};
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/*
* Loader private data, hung off <so_map>->som_spd
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*/
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 */
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#ifdef SUN_COMPAT
long spd_offset; /* Correction for Sun main programs */
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#endif
};
#define LM_PRIVATE(smp) ((struct somap_private *)(smp)->som_spd)
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#ifdef SUN_COMPAT
#define LM_OFFSET(smp) (LM_PRIVATE(smp)->spd_offset)
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#else
#define LM_OFFSET(smp) (0)
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#endif
/* Base address for section_dispatch_table entries */
#define LM_LDBASE(smp) (smp->som_addr + LM_OFFSET(smp))
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/* Start of text segment */
#define LM_TXTADDR(smp) (smp->som_addr == (caddr_t)0 ? PAGSIZ : 0)
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/* Start of run-time relocation_info */
#define LM_REL(smp) ((struct relocation_info *) \
(smp->som_addr + LM_OFFSET(smp) + LD_REL((smp)->som_dynamic)))
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/* 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))))
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/* Start of hash table */
#define LM_HASH(smp) ((struct rrs_hash *) \
((smp)->som_addr + LM_OFFSET(smp) + LD_HASH((smp)->som_dynamic)))
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/* Start of strings */
#define LM_STRINGS(smp) ((char *) \
((smp)->som_addr + LM_OFFSET(smp) + LD_STRINGS((smp)->som_dynamic)))
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/* Start of search paths */
#define LM_PATHS(smp) ((char *) \
((smp)->som_addr + LM_OFFSET(smp) + LD_PATHS((smp)->som_dynamic)))
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/* End of text */
#define LM_ETEXT(smp) ((char *) \
((smp)->som_addr + LM_TXTADDR(smp) + LD_TEXTSZ((smp)->som_dynamic)))
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/* Needed shared objects */
#define LM_NEED(smp) ((struct sod *) \
((smp)->som_addr + LM_TXTADDR(smp) + LD_NEED((smp)->som_dynamic)))
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/* 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)))
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/* Parent of link map */
#define LM_PARENT(smp) (LM_PRIVATE(smp)->spd_parent)
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#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
static char __main_progname[] = "main";
static char *main_progname = __main_progname;
static char us[] = "/usr/libexec/ld.so";
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char **environ;
char *__progname;
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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;
Changed the terminology for what used to be called the "memorizing" vector. Now it is called the "symbol caching" vector. This was made possible and unconfusing by other changes that allowed me to localize everything having to do with the caching vector in the function reloc_map(). Switched to alloca() for allocating the caching vector, and eliminated the special mmap-based allocation routines. Although this was motivated by performance reasons, it led to significant simplification of the code, and made it possible to confine the symbol caching code to the single function reloc_map(). Got rid of the unnecessary and inefficient division loop at the beginning of rtld(). Reduced the number of calls to getenv("LD_LIBRARY_PATH") to just 1, on suggestion from <davidg@root.com>. Added breaks out of the relocation loops when the relocation address is found to be 0. A relocation address of 0 is caused by an unused relocation entry. Unused relocation entries are caused by linking a shared object with the "-Bsymbolic" switch. The runtime linker itself is linked that way, and the last 40% of its relocation entries are unused. Thus, breaking out of the loop on the first such entry is a performance win when ld.so relocates itself. As a side benefit, it permits removing a test from md_relocate_simple() in ../i386/md-static-funcs.c. Unused relocation entries in other shared objects (linked with "-Bsymbolic") caused even bigger problems in previous versions of the runtime linker. The runtime linker interpreted the unused entries as if they were valid. That caused it to perform repeated relocations of the first byte of the shared object. In order to do that, it had to remap the text segment writable. Breaking out of the loop on the first unused relocation entry solves that. Submitted by: John Polstra <jdp@polstra.com>
1995-11-02 18:48:15 +00:00
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;
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struct so_map *link_map_head;
struct so_map *link_map_tail;
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struct rt_symbol *rt_symbol_head;
static void *__dlopen __P((char *, int));
static int __dlclose __P((void *));
static void *__dlsym __P((void *, char *));
static char *__dlerror __P((void));
static void __dlexit __P((void));
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static struct ld_entry ld_entry = {
__dlopen, __dlclose, __dlsym, __dlerror, __dlexit
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};
void xprintf __P((char *, ...));
static struct so_map *map_object __P(( char *,
struct sod *,
struct so_map *));
static int map_preload __P((void));
static int map_sods __P((struct so_map *));
static int reloc_and_init __P((struct so_map *, int));
static void unmap_object __P((struct so_map *, int));
static struct so_map *alloc_link_map __P(( 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 *,
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caddr_t));
static int reloc_map __P((struct so_map *, int));
static void reloc_copy __P((struct so_map *));
static void init_object __P((struct so_map *));
static void init_sods __P((struct so_list *));
static int call_map __P((struct so_map *, char *));
static char *findhint __P((char *, int, int *));
static char *rtfindlib __P((char *, int, int));
static char *rtfindfile __P((char *));
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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 *));
static struct rt_symbol *enter_rts __P((char *, long, int, caddr_t,
long, struct so_map *));
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 *));
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);
}
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#include "md-static-funcs.c"
/*
* Called from assembler stub that has set up crtp (passed from crt0)
* and dp (our __DYNAMIC).
*/
int
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rtld(version, crtp, dp)
int version;
struct crt_ldso *crtp;
struct _dynamic *dp;
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{
struct relocation_info *reloc;
Changed the terminology for what used to be called the "memorizing" vector. Now it is called the "symbol caching" vector. This was made possible and unconfusing by other changes that allowed me to localize everything having to do with the caching vector in the function reloc_map(). Switched to alloca() for allocating the caching vector, and eliminated the special mmap-based allocation routines. Although this was motivated by performance reasons, it led to significant simplification of the code, and made it possible to confine the symbol caching code to the single function reloc_map(). Got rid of the unnecessary and inefficient division loop at the beginning of rtld(). Reduced the number of calls to getenv("LD_LIBRARY_PATH") to just 1, on suggestion from <davidg@root.com>. Added breaks out of the relocation loops when the relocation address is found to be 0. A relocation address of 0 is caused by an unused relocation entry. Unused relocation entries are caused by linking a shared object with the "-Bsymbolic" switch. The runtime linker itself is linked that way, and the last 40% of its relocation entries are unused. Thus, breaking out of the loop on the first such entry is a performance win when ld.so relocates itself. As a side benefit, it permits removing a test from md_relocate_simple() in ../i386/md-static-funcs.c. Unused relocation entries in other shared objects (linked with "-Bsymbolic") caused even bigger problems in previous versions of the runtime linker. The runtime linker interpreted the unused entries as if they were valid. That caused it to perform repeated relocations of the first byte of the shared object. In order to do that, it had to remap the text segment writable. Breaking out of the loop on the first unused relocation entry solves that. Submitted by: John Polstra <jdp@polstra.com>
1995-11-02 18:48:15 +00:00
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;
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/* Check version */
if (version != CRT_VERSION_BSD_2 &&
version != CRT_VERSION_BSD_3 &&
version != CRT_VERSION_BSD_4 &&
version != CRT_VERSION_SUN)
return -1;
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/* Fixup __DYNAMIC structure */
(long)dp->d_un.d_sdt += crtp->crt_ba;
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/* Relocate ourselves */
Changed the terminology for what used to be called the "memorizing" vector. Now it is called the "symbol caching" vector. This was made possible and unconfusing by other changes that allowed me to localize everything having to do with the caching vector in the function reloc_map(). Switched to alloca() for allocating the caching vector, and eliminated the special mmap-based allocation routines. Although this was motivated by performance reasons, it led to significant simplification of the code, and made it possible to confine the symbol caching code to the single function reloc_map(). Got rid of the unnecessary and inefficient division loop at the beginning of rtld(). Reduced the number of calls to getenv("LD_LIBRARY_PATH") to just 1, on suggestion from <davidg@root.com>. Added breaks out of the relocation loops when the relocation address is found to be 0. A relocation address of 0 is caused by an unused relocation entry. Unused relocation entries are caused by linking a shared object with the "-Bsymbolic" switch. The runtime linker itself is linked that way, and the last 40% of its relocation entries are unused. Thus, breaking out of the loop on the first such entry is a performance win when ld.so relocates itself. As a side benefit, it permits removing a test from md_relocate_simple() in ../i386/md-static-funcs.c. Unused relocation entries in other shared objects (linked with "-Bsymbolic") caused even bigger problems in previous versions of the runtime linker. The runtime linker interpreted the unused entries as if they were valid. That caused it to perform repeated relocations of the first byte of the shared object. In order to do that, it had to remap the text segment writable. Breaking out of the loop on the first unused relocation entry solves that. Submitted by: John Polstra <jdp@polstra.com>
1995-11-02 18:48:15 +00:00
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;
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}
if (version >= CRT_VERSION_BSD_4)
__progname = crtp->crt_ldso;
if (version >= CRT_VERSION_BSD_3)
main_progname = crtp->crt_prog;
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/* 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 */
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/* 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();
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anon_open();
/* Make a link map entry for the main program */
main_map = alloc_link_map(main_progname,
(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;
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/*
* 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 and initialize all mapped objects */
if(reloc_and_init(main_map, ld_bind_now != NULL) == -1) /* Failed */
die();
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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_DLEXIT;
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}
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;
}
}
}
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/*
* 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.
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*/
static struct so_map *
alloc_link_map(path, sodp, parent, addr, dp)
char *path;
struct sod *sodp;
struct so_map *parent;
caddr_t addr;
struct _dynamic *dp;
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{
struct so_map *smp;
struct somap_private *smpp;
size_t smp_size;
#ifdef DEBUG /* { */
xprintf("alloc_link_map: \"%s\" at %p\n", path, addr);
#endif /* } */
/*
* Allocate so_map and private area with a single malloc. Round
* up the size of so_map so the private area is aligned.
*/
smp_size = ((((sizeof(struct so_map)) + sizeof (void *) - 1) /
sizeof (void *)) * sizeof (void *));
smp = (struct so_map *)xmalloc(smp_size +
sizeof (struct somap_private));
smpp = (struct somap_private *) (((caddr_t) smp) + smp_size);
/* Link the new entry into the list of link maps */
smp->som_next = NULL;
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;
}
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smp->som_addr = addr;
smp->som_path = path ? strdup(path) : NULL;
smp->som_sod = sodp;
smp->som_dynamic = dp;
smp->som_spd = (caddr_t)smpp;
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smpp->spd_refcount = 0;
smpp->spd_flags = 0;
smpp->spd_parent = parent;
smpp->spd_children = NULL;
smpp->a_text = 0;
smpp->a_data = 0;
smpp->a_bss = 0;
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#ifdef SUN_COMPAT
smpp->spd_offset =
(addr==0 && dp && dp->d_version==LD_VERSION_SUN) ? PAGSIZ : 0;
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#endif
return smp;
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}
/*
* 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;
free(smp->som_path);
free(smp);
}
1993-11-03 23:41:59 +00:00
/*
* 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().
1993-11-03 23:41:59 +00:00
*/
static struct so_map *
map_object(path, sodp, parent)
char *path;
struct sod *sodp;
struct so_map *parent;
1993-11-03 23:41:59 +00:00
{
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;
}
1993-11-03 23:41:59 +00:00
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;
1993-11-03 23:41:59 +00:00
}
(void)close(fd);
1993-11-03 23:41:59 +00:00
/* 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;
}
1993-11-03 23:41:59 +00:00
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;
}
}
1993-11-03 23:41:59 +00:00
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) {
path = rtfindlib(name, sodp->sod_major,
sodp->sod_minor);
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 /* Give up */
break;
next = sodp->sod_next;
}
1993-11-03 23:41:59 +00:00
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;
}
1993-11-03 23:41:59 +00:00
return 0;
}
1993-11-03 23:41:59 +00:00
/*
* Relocate and initialize the tree 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_and_init(root, bind_now)
struct so_map *root;
int bind_now;
{
struct so_map *smp;
1993-11-03 23:41:59 +00:00
/*
* 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;
}
}
1993-11-03 23:41:59 +00:00
/*
* 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);
}
1995-05-30 05:05:38 +00:00
/*
* Call any object initialization routines.
*
* Here, the order is very important, and we cannot simply loop
* over the newly-loaded objects as we did before. Rather, we
* have to initialize the tree of new objects depth-first, and
* process the sibling objects at each level in reverse order
* relative to the dependency list.
*
* Here is the reason we initialize depth-first. If an object
* depends on one or more other objects, then the objects it
* depends on should be initialized first, before the parent
* object itself. For it is possible that the parent's
* initialization routine will need the services provided by the
* objects it depends on -- and those objects had better already
* be initialized.
*
* We initialize the objects at each level of the tree in reverse
* order for a similar reason. When an object is linked with
* several libraries, it is common for routines in the earlier
* libraries to call routines in the later libraries. So, again,
* the later libraries need to be initialized first.
*
* The upshot of these rules is that we have to use recursion to
* get the libraries initialized in the best order. But the
* recursion is never likely to be very deep.
*/
init_object(root);
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);
}
}
1993-11-03 23:41:59 +00:00
}
static inline int
check_text_reloc(r, smp, addr)
struct relocation_info *r;
struct so_map *smp;
caddr_t addr;
1993-11-03 23:41:59 +00:00
{
char *sym;
1993-11-03 23:41:59 +00:00
if (addr >= LM_ETEXT(smp))
return 0;
1993-11-03 23:41:59 +00:00
if (RELOC_EXTERN_P(r))
sym = LM_STRINGS(smp) +
LM_SYMBOL(smp, RELOC_SYMBOL(r))->nz_strx;
else
sym = "";
1993-11-03 23:41:59 +00:00
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;
}
1993-11-03 23:41:59 +00:00
smp->som_write = 1;
return 0;
}
1993-11-03 23:41:59 +00:00
static int
reloc_map(smp, bind_now)
struct so_map *smp;
int bind_now;
{
Changed the terminology for what used to be called the "memorizing" vector. Now it is called the "symbol caching" vector. This was made possible and unconfusing by other changes that allowed me to localize everything having to do with the caching vector in the function reloc_map(). Switched to alloca() for allocating the caching vector, and eliminated the special mmap-based allocation routines. Although this was motivated by performance reasons, it led to significant simplification of the code, and made it possible to confine the symbol caching code to the single function reloc_map(). Got rid of the unnecessary and inefficient division loop at the beginning of rtld(). Reduced the number of calls to getenv("LD_LIBRARY_PATH") to just 1, on suggestion from <davidg@root.com>. Added breaks out of the relocation loops when the relocation address is found to be 0. A relocation address of 0 is caused by an unused relocation entry. Unused relocation entries are caused by linking a shared object with the "-Bsymbolic" switch. The runtime linker itself is linked that way, and the last 40% of its relocation entries are unused. Thus, breaking out of the loop on the first such entry is a performance win when ld.so relocates itself. As a side benefit, it permits removing a test from md_relocate_simple() in ../i386/md-static-funcs.c. Unused relocation entries in other shared objects (linked with "-Bsymbolic") caused even bigger problems in previous versions of the runtime linker. The runtime linker interpreted the unused entries as if they were valid. That caused it to perform repeated relocations of the first byte of the shared object. In order to do that, it had to remap the text segment writable. Breaking out of the loop on the first unused relocation entry solves that. Submitted by: John Polstra <jdp@polstra.com>
1995-11-02 18:48:15 +00:00
/*
* 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);
Changed the terminology for what used to be called the "memorizing" vector. Now it is called the "symbol caching" vector. This was made possible and unconfusing by other changes that allowed me to localize everything having to do with the caching vector in the function reloc_map(). Switched to alloca() for allocating the caching vector, and eliminated the special mmap-based allocation routines. Although this was motivated by performance reasons, it led to significant simplification of the code, and made it possible to confine the symbol caching code to the single function reloc_map(). Got rid of the unnecessary and inefficient division loop at the beginning of rtld(). Reduced the number of calls to getenv("LD_LIBRARY_PATH") to just 1, on suggestion from <davidg@root.com>. Added breaks out of the relocation loops when the relocation address is found to be 0. A relocation address of 0 is caused by an unused relocation entry. Unused relocation entries are caused by linking a shared object with the "-Bsymbolic" switch. The runtime linker itself is linked that way, and the last 40% of its relocation entries are unused. Thus, breaking out of the loop on the first such entry is a performance win when ld.so relocates itself. As a side benefit, it permits removing a test from md_relocate_simple() in ../i386/md-static-funcs.c. Unused relocation entries in other shared objects (linked with "-Bsymbolic") caused even bigger problems in previous versions of the runtime linker. The runtime linker interpreted the unused entries as if they were valid. That caused it to perform repeated relocations of the first byte of the shared object. In order to do that, it had to remap the text segment writable. Breaking out of the loop on the first unused relocation entry solves that. Submitted by: John Polstra <jdp@polstra.com>
1995-11-02 18:48:15 +00:00
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;
}
Changed the terminology for what used to be called the "memorizing" vector. Now it is called the "symbol caching" vector. This was made possible and unconfusing by other changes that allowed me to localize everything having to do with the caching vector in the function reloc_map(). Switched to alloca() for allocating the caching vector, and eliminated the special mmap-based allocation routines. Although this was motivated by performance reasons, it led to significant simplification of the code, and made it possible to confine the symbol caching code to the single function reloc_map(). Got rid of the unnecessary and inefficient division loop at the beginning of rtld(). Reduced the number of calls to getenv("LD_LIBRARY_PATH") to just 1, on suggestion from <davidg@root.com>. Added breaks out of the relocation loops when the relocation address is found to be 0. A relocation address of 0 is caused by an unused relocation entry. Unused relocation entries are caused by linking a shared object with the "-Bsymbolic" switch. The runtime linker itself is linked that way, and the last 40% of its relocation entries are unused. Thus, breaking out of the loop on the first such entry is a performance win when ld.so relocates itself. As a side benefit, it permits removing a test from md_relocate_simple() in ../i386/md-static-funcs.c. Unused relocation entries in other shared objects (linked with "-Bsymbolic") caused even bigger problems in previous versions of the runtime linker. The runtime linker interpreted the unused entries as if they were valid. That caused it to perform repeated relocations of the first byte of the shared object. In order to do that, it had to remap the text segment writable. Breaking out of the loop on the first unused relocation entry solves that. Submitted by: John Polstra <jdp@polstra.com>
1995-11-02 18:48:15 +00:00
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;
Changed the terminology for what used to be called the "memorizing" vector. Now it is called the "symbol caching" vector. This was made possible and unconfusing by other changes that allowed me to localize everything having to do with the caching vector in the function reloc_map(). Switched to alloca() for allocating the caching vector, and eliminated the special mmap-based allocation routines. Although this was motivated by performance reasons, it led to significant simplification of the code, and made it possible to confine the symbol caching code to the single function reloc_map(). Got rid of the unnecessary and inefficient division loop at the beginning of rtld(). Reduced the number of calls to getenv("LD_LIBRARY_PATH") to just 1, on suggestion from <davidg@root.com>. Added breaks out of the relocation loops when the relocation address is found to be 0. A relocation address of 0 is caused by an unused relocation entry. Unused relocation entries are caused by linking a shared object with the "-Bsymbolic" switch. The runtime linker itself is linked that way, and the last 40% of its relocation entries are unused. Thus, breaking out of the loop on the first such entry is a performance win when ld.so relocates itself. As a side benefit, it permits removing a test from md_relocate_simple() in ../i386/md-static-funcs.c. Unused relocation entries in other shared objects (linked with "-Bsymbolic") caused even bigger problems in previous versions of the runtime linker. The runtime linker interpreted the unused entries as if they were valid. That caused it to perform repeated relocations of the first byte of the shared object. In order to do that, it had to remap the text segment writable. Breaking out of the loop on the first unused relocation entry solves that. Submitted by: John Polstra <jdp@polstra.com>
1995-11-02 18:48:15 +00:00
caddr_t addr;
Changed the terminology for what used to be called the "memorizing" vector. Now it is called the "symbol caching" vector. This was made possible and unconfusing by other changes that allowed me to localize everything having to do with the caching vector in the function reloc_map(). Switched to alloca() for allocating the caching vector, and eliminated the special mmap-based allocation routines. Although this was motivated by performance reasons, it led to significant simplification of the code, and made it possible to confine the symbol caching code to the single function reloc_map(). Got rid of the unnecessary and inefficient division loop at the beginning of rtld(). Reduced the number of calls to getenv("LD_LIBRARY_PATH") to just 1, on suggestion from <davidg@root.com>. Added breaks out of the relocation loops when the relocation address is found to be 0. A relocation address of 0 is caused by an unused relocation entry. Unused relocation entries are caused by linking a shared object with the "-Bsymbolic" switch. The runtime linker itself is linked that way, and the last 40% of its relocation entries are unused. Thus, breaking out of the loop on the first such entry is a performance win when ld.so relocates itself. As a side benefit, it permits removing a test from md_relocate_simple() in ../i386/md-static-funcs.c. Unused relocation entries in other shared objects (linked with "-Bsymbolic") caused even bigger problems in previous versions of the runtime linker. The runtime linker interpreted the unused entries as if they were valid. That caused it to perform repeated relocations of the first byte of the shared object. In order to do that, it had to remap the text segment writable. Breaking out of the loop on the first unused relocation entry solves that. Submitted by: John Polstra <jdp@polstra.com>
1995-11-02 18:48:15 +00:00
/*
* 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;
1993-11-03 23:41:59 +00:00
p = (struct nzlist *)
(symbolbase + symsize * RELOC_SYMBOL(r));
if (p->nz_type == (N_SETV + N_EXT))
src_map = smp;
sym = stringbase + p->nz_strx;
Changed the terminology for what used to be called the "memorizing" vector. Now it is called the "symbol caching" vector. This was made possible and unconfusing by other changes that allowed me to localize everything having to do with the caching vector in the function reloc_map(). Switched to alloca() for allocating the caching vector, and eliminated the special mmap-based allocation routines. Although this was motivated by performance reasons, it led to significant simplification of the code, and made it possible to confine the symbol caching code to the single function reloc_map(). Got rid of the unnecessary and inefficient division loop at the beginning of rtld(). Reduced the number of calls to getenv("LD_LIBRARY_PATH") to just 1, on suggestion from <davidg@root.com>. Added breaks out of the relocation loops when the relocation address is found to be 0. A relocation address of 0 is caused by an unused relocation entry. Unused relocation entries are caused by linking a shared object with the "-Bsymbolic" switch. The runtime linker itself is linked that way, and the last 40% of its relocation entries are unused. Thus, breaking out of the loop on the first such entry is a performance win when ld.so relocates itself. As a side benefit, it permits removing a test from md_relocate_simple() in ../i386/md-static-funcs.c. Unused relocation entries in other shared objects (linked with "-Bsymbolic") caused even bigger problems in previous versions of the runtime linker. The runtime linker interpreted the unused entries as if they were valid. That caused it to perform repeated relocations of the first byte of the shared object. In order to do that, it had to remap the text segment writable. Breaking out of the loop on the first unused relocation entry solves that. Submitted by: John Polstra <jdp@polstra.com>
1995-11-02 18:48:15 +00:00
/*
* 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));
Changed the terminology for what used to be called the "memorizing" vector. Now it is called the "symbol caching" vector. This was made possible and unconfusing by other changes that allowed me to localize everything having to do with the caching vector in the function reloc_map(). Switched to alloca() for allocating the caching vector, and eliminated the special mmap-based allocation routines. Although this was motivated by performance reasons, it led to significant simplification of the code, and made it possible to confine the symbol caching code to the single function reloc_map(). Got rid of the unnecessary and inefficient division loop at the beginning of rtld(). Reduced the number of calls to getenv("LD_LIBRARY_PATH") to just 1, on suggestion from <davidg@root.com>. Added breaks out of the relocation loops when the relocation address is found to be 0. A relocation address of 0 is caused by an unused relocation entry. Unused relocation entries are caused by linking a shared object with the "-Bsymbolic" switch. The runtime linker itself is linked that way, and the last 40% of its relocation entries are unused. Thus, breaking out of the loop on the first such entry is a performance win when ld.so relocates itself. As a side benefit, it permits removing a test from md_relocate_simple() in ../i386/md-static-funcs.c. Unused relocation entries in other shared objects (linked with "-Bsymbolic") caused even bigger problems in previous versions of the runtime linker. The runtime linker interpreted the unused entries as if they were valid. That caused it to perform repeated relocations of the first byte of the shared object. In order to do that, it had to remap the text segment writable. Breaking out of the loop on the first unused relocation entry solves that. Submitted by: John Polstra <jdp@polstra.com>
1995-11-02 18:48:15 +00:00
/*
* 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;
}
Changed the terminology for what used to be called the "memorizing" vector. Now it is called the "symbol caching" vector. This was made possible and unconfusing by other changes that allowed me to localize everything having to do with the caching vector in the function reloc_map(). Switched to alloca() for allocating the caching vector, and eliminated the special mmap-based allocation routines. Although this was motivated by performance reasons, it led to significant simplification of the code, and made it possible to confine the symbol caching code to the single function reloc_map(). Got rid of the unnecessary and inefficient division loop at the beginning of rtld(). Reduced the number of calls to getenv("LD_LIBRARY_PATH") to just 1, on suggestion from <davidg@root.com>. Added breaks out of the relocation loops when the relocation address is found to be 0. A relocation address of 0 is caused by an unused relocation entry. Unused relocation entries are caused by linking a shared object with the "-Bsymbolic" switch. The runtime linker itself is linked that way, and the last 40% of its relocation entries are unused. Thus, breaking out of the loop on the first such entry is a performance win when ld.so relocates itself. As a side benefit, it permits removing a test from md_relocate_simple() in ../i386/md-static-funcs.c. Unused relocation entries in other shared objects (linked with "-Bsymbolic") caused even bigger problems in previous versions of the runtime linker. The runtime linker interpreted the unused entries as if they were valid. That caused it to perform repeated relocations of the first byte of the shared object. In order to do that, it had to remap the text segment writable. Breaking out of the loop on the first unused relocation entry solves that. Submitted by: John Polstra <jdp@polstra.com>
1995-11-02 18:48:15 +00:00
/*
* 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,
(long)addr,
N_DATA + N_EXT,
src_map->som_addr + np->nz_value,
np->nz_size, src_map);
continue;
}
1993-11-03 23:41:59 +00:00
md_relocate(r, relocation, addr, 0);
} else {
md_relocate(r,
1993-11-03 23:41:59 +00:00
#ifdef SUN_COMPAT
md_get_rt_segment_addend(r, addr)
1993-11-03 23:41:59 +00:00
#else
md_get_addend(r, addr)
1993-11-03 23:41:59 +00:00
#endif
+ (long)smp->som_addr, addr, 0);
1993-11-03 23:41:59 +00:00
}
}
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;
1993-11-03 23:41:59 +00:00
}
return 0;
1993-11-03 23:41:59 +00:00
}
static void
reloc_copy(smp)
struct so_map *smp;
1993-11-03 23:41:59 +00:00
{
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) {
1993-11-03 23:41:59 +00:00
bcopy(rtsp->rt_srcaddr, (caddr_t)rtsp->rt_sp->nz_value,
rtsp->rt_sp->nz_size);
}
}
static void
init_object(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_object(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;
1993-11-03 23:41:59 +00:00
{
struct so_map *src_map = smp;
struct nzlist *np;
1993-11-03 23:41:59 +00:00
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.
*/
1993-11-03 23:41:59 +00:00
#define RTC_TABSIZE 57
static struct rt_symbol *rt_symtab[RTC_TABSIZE];
1993-11-03 23:41:59 +00:00
/*
* Compute hash value for run-time symbol table
*/
static inline int
hash_string(key)
char *key;
{
register char *cp;
register int k;
1993-11-03 23:41:59 +00:00
cp = key;
k = 0;
while (*cp)
k = (((k << 1) + (k >> 14)) ^ (*cp++)) & 0x3fff;
1993-11-03 23:41:59 +00:00
return k;
1993-11-03 23:41:59 +00:00
}
/*
* Lookup KEY in the run-time common symbol table.
*/
static inline struct rt_symbol *
lookup_rts(key)
char *key;
{
register int hashval;
register struct rt_symbol *rtsp;
/* Determine which bucket. */
hashval = hash_string(key) % RTC_TABSIZE;
/* Search the bucket. */
for (rtsp = rt_symtab[hashval]; rtsp; rtsp = rtsp->rt_link)
if (strcmp(key, rtsp->rt_sp->nz_name) == 0)
return rtsp;
return NULL;
}
static struct rt_symbol *
enter_rts(name, value, type, srcaddr, size, smp)
char *name;
long value;
int type;
caddr_t srcaddr;
long size;
struct so_map *smp;
{
register int hashval;
register struct rt_symbol *rtsp, **rpp;
/* Determine which bucket */
hashval = hash_string(name) % RTC_TABSIZE;
/* Find end of bucket */
for (rpp = &rt_symtab[hashval]; *rpp; rpp = &(*rpp)->rt_link)
continue;
/* Allocate new common symbol */
rtsp = (struct rt_symbol *)malloc(sizeof(struct rt_symbol));
rtsp->rt_sp = (struct nzlist *)malloc(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. If STRONG is set, the symbol returned must
* have a proper type (used by binder()).
*/
static struct nzlist *
lookup(name, src_map, strong)
char *name;
struct so_map **src_map; /* IN/OUT */
int strong;
1993-11-03 23:41:59 +00:00
{
long common_size = 0;
struct so_map *smp;
1993-11-03 23:41:59 +00:00
struct rt_symbol *rtsp;
if ((rtsp = lookup_rts(name)) != NULL)
return rtsp->rt_sp;
/*
* Search all maps for a definition of NAME
*/
for (smp = link_map_head; smp; smp = smp->som_next) {
int buckets;
long hashval;
1993-11-03 23:41:59 +00:00
struct rrs_hash *hp;
char *cp;
struct nzlist *np;
/* Some local caching */
long symbolbase;
struct rrs_hash *hashbase;
char *stringbase;
int symsize;
if (*src_map && smp != *src_map)
continue;
if ((buckets = LD_BUCKETS(smp->som_dynamic)) == 0)
1995-05-30 05:05:38 +00:00
continue;
if (LM_PRIVATE(smp)->spd_flags & RTLD_RTLD)
continue;
restart:
1993-11-03 23:41:59 +00:00
/*
* Compute bucket in which the symbol might be found.
*/
for (hashval = 0, cp = name; *cp; cp++)
1993-11-03 23:41:59 +00:00
hashval = (hashval << 1) + *cp;
hashval = (hashval & 0x7fffffff) % buckets;
hashbase = LM_HASH(smp);
hp = hashbase + hashval;
1993-11-03 23:41:59 +00:00
if (hp->rh_symbolnum == -1)
/* Nothing in this bucket */
continue;
symbolbase = (long)LM_SYMBOL(smp, 0);
stringbase = LM_STRINGS(smp);
symsize = LD_VERSION_NZLIST_P(smp->som_dynamic->d_version)?
sizeof(struct nzlist) :
sizeof(struct nlist);
1993-11-03 23:41:59 +00:00
while (hp) {
np = (struct nzlist *)
(symbolbase + hp->rh_symbolnum * symsize);
cp = stringbase + np->nz_strx;
1993-11-03 23:41:59 +00:00
if (strcmp(cp, name) == 0)
break;
if (hp->rh_next == 0)
hp = NULL;
else
hp = hashbase + hp->rh_next;
1993-11-03 23:41:59 +00:00
}
if (hp == NULL)
/* Nothing in this bucket */
continue;
/*
* 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 and confine to this map.
*/
name = stringbase + (++np)->nz_strx;
*src_map = smp;
goto restart;
}
1993-11-03 23:41:59 +00:00
if (np->nz_value == 0)
/* It's not a definition */
continue;
if (np->nz_type == N_UNDF+N_EXT && np->nz_value != 0) {
if (np->nz_other == AUX_FUNC) {
/* It's a weak function definition */
if (strong)
continue;
} else {
/* It's a common, note value and continue search */
if (common_size < np->nz_value)
common_size = np->nz_value;
continue;
}
1993-11-03 23:41:59 +00:00
}
*src_map = smp;
1993-11-03 23:41:59 +00:00
return np;
}
if (common_size == 0)
/* Not found */
return NULL;
/*
* It's a common, enter into run-time common symbol table.
*/
rtsp = enter_rts(name, (long)calloc(1, common_size),
N_UNDF + N_EXT, 0, common_size, NULL);
1993-11-03 23:41:59 +00:00
#if DEBUG
xprintf("Allocating common: %s size %d at %#x\n", name, common_size,
rtsp->rt_sp->nz_value);
1993-11-03 23:41:59 +00:00
#endif
return rtsp->rt_sp;
}
/*
* This routine is called from the jumptable to resolve
* procedure calls to shared objects.
*/
long
1993-11-03 23:41:59 +00:00
binder(jsp)
jmpslot_t *jsp;
1993-11-03 23:41:59 +00:00
{
struct so_map *smp, *src_map = NULL;
1993-11-03 23:41:59 +00:00
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))
1993-11-03 23:41:59 +00:00
break;
}
if (smp == NULL)
errx(1, "Call to binder from unknown location: %#x\n", jsp);
1993-11-03 23:41:59 +00:00
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;
1993-11-03 23:41:59 +00:00
np = lookup(sym, &src_map, 1);
1993-11-03 23:41:59 +00:00
if (np == NULL)
errx(1, "Undefined symbol \"%s\" called from %s:%s at %#x",
sym, main_progname, smp->som_path, jsp);
1993-11-03 23:41:59 +00:00
/* Fixup jmpslot so future calls transfer directly to target */
addr = np->nz_value;
if (src_map)
addr += (long)src_map->som_addr;
1993-11-03 23:41:59 +00:00
md_fix_jmpslot(jsp, (long)jsp, addr);
#if DEBUG
xprintf(" BINDER: %s located at = %#x in %s\n", sym, addr,
src_map->som_path);
1993-11-03 23:41:59 +00:00
#endif
return addr;
}
static struct hints_header *hheader; /* NULL means not mapped */
1993-11-03 23:41:59 +00:00
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))
1993-11-03 23:41:59 +00:00
{
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;
1993-11-03 23:41:59 +00:00
if ((hfd = open(_PATH_LD_HINTS, O_RDONLY, 0)) == -1) {
hints_bad = 1;
return -1;
1993-11-03 23:41:59 +00:00
}
/* Read the header and check it */
1993-11-03 23:41:59 +00:00
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;
1993-11-03 23:41:59 +00:00
}
/* Map the hints into memory */
1993-11-03 23:41:59 +00:00
addr = mmap(0, hdr.hh_ehints, PROT_READ, MAP_SHARED, hfd, 0);
if (addr == (caddr_t)-1) {
close(hfd);
hints_bad = 1;
return -1;
1993-11-03 23:41:59 +00:00
}
close(hfd);
1993-11-03 23:41:59 +00:00
hheader = (struct hints_header *)addr;
1993-11-03 23:41:59 +00:00
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;
1993-11-03 23:41:59 +00:00
}
/*
* 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;
1993-11-03 23:41:59 +00:00
{
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.
*
* Returns the minor number of the matching library via the pointer
* argument MINORP.
*
* Returns NULL if the library cannot be found.
*/
static char *
findhint(name, major, minorp)
char *name;
int major;
int *minorp;
1993-11-03 23:41:59 +00:00
{
struct hints_bucket *bp =
hbuckets + (hinthash(name, major) % hheader->hh_nbucket);
1993-11-03 23:41:59 +00:00
while (1) {
/* Sanity check */
if (bp->hi_namex >= hheader->hh_strtab_sz) {
warnx("Bad name index: %#x\n", bp->hi_namex);
1993-11-03 23:41:59 +00:00
break;
}
if (bp->hi_pathx >= hheader->hh_strtab_sz) {
warnx("Bad path index: %#x\n", bp->hi_pathx);
1993-11-03 23:41:59 +00:00
break;
}
/*
* We accept the current hints entry if its name matches
* and its major number matches. We don't have to search
* for the best minor number, because that was already
* done by "ldconfig" when it built the hints file.
*/
if (strcmp(name, hstrtab + bp->hi_namex) == 0 &&
bp->hi_major == major) {
struct stat s;
if (stat(hstrtab + bp->hi_pathx, &s) == -1)
return NULL; /* Doesn't actually exist */
*minorp = bp->hi_ndewey >= 2 ? bp->hi_minor : -1;
return strdup(hstrtab + bp->hi_pathx);
1993-11-03 23:41:59 +00:00
}
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)
char *name;
int major, minor;
1993-11-03 23:41:59 +00:00
{
char *ld_path = ld_library_path;
char *path = NULL;
int realminor = -1;
1993-11-03 23:41:59 +00:00
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;
1993-11-03 23:41:59 +00:00
while (path == NULL && (dir = strsep(&ld_path, ":")) != NULL) {
path = search_lib_dir(dir, name, &major, &realminor, 0);
if (ld_path != NULL)
*(ld_path - 1) = ':';
1993-11-03 23:41:59 +00:00
}
}
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);
1993-11-03 23:41:59 +00:00
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)
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)
char *path;
int mode;
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{
struct so_map *old_tail = link_map_tail;
struct so_map *smp;
int bind_now = mode == RTLD_NOW;
/*
* path == NULL is handled by map_object()
*/
anon_open();
/* Map the object, and the objects on which it depends */
smp = map_object(path, (struct sod *) NULL, (struct so_map *) NULL);
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_and_init(smp, bind_now) == -1) /* Failed */
return NULL;
}
unmaphints();
anon_close();
return smp;
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}
static int
__dlclose(fd)
void *fd;
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{
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;
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}
static void *
__dlsym(fd, sym)
void *fd;
char *sym;
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{
struct so_map *smp = (struct so_map *)fd, *src_map = NULL;
struct nzlist *np;
long addr;
/*
* 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)
return NULL;
/* Fixup jmpslot so future calls transfer directly to target */
addr = np->nz_value;
if (src_map)
addr += (long)src_map->som_addr;
return (void *)addr;
}
static char *
__dlerror __P((void))
{
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))
{
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
#if __STDC__
generror(char *fmt, ...)
#else
generror(fmt, va_alist)
char *fmt;
#endif
{
va_list ap;
#if __STDC__
va_start(ap, fmt);
#else
va_start(ap);
#endif
vsnprintf (dlerror_buf, DLERROR_BUF_SIZE, fmt, ap);
dlerror_msg = dlerror_buf;
va_end(ap);
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}
void
#if __STDC__
xprintf(char *fmt, ...)
#else
xprintf(fmt, va_alist)
char *fmt;
#endif
{
char buf[256];
va_list ap;
#if __STDC__
va_start(ap, fmt);
#else
va_start(ap);
#endif
vsnprintf(buf, sizeof(buf), fmt, ap);
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(void)write(1, 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_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, 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;
}
}
}
}