musl/ldso/dynlink.c

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#define _GNU_SOURCE
#include <stdio.h>
#include <stdlib.h>
#include <stdarg.h>
#include <stddef.h>
#include <string.h>
#include <unistd.h>
#include <stdint.h>
#include <elf.h>
#include <sys/mman.h>
#include <limits.h>
#include <fcntl.h>
#include <sys/stat.h>
#include <errno.h>
#include <link.h>
#include <setjmp.h>
#include <pthread.h>
2011-08-16 04:24:36 +00:00
#include <ctype.h>
#include <dlfcn.h>
#include "pthread_impl.h"
#include "libc.h"
#include "dynlink.h"
#include "malloc_impl.h"
static void error(const char *, ...);
#define MAXP2(a,b) (-(-(a)&-(b)))
#define ALIGN(x,y) ((x)+(y)-1 & -(y))
struct debug {
int ver;
void *head;
void (*bp)(void);
int state;
void *base;
};
struct td_index {
size_t args[2];
struct td_index *next;
};
struct dso {
#if DL_FDPIC
struct fdpic_loadmap *loadmap;
#else
unsigned char *base;
#endif
char *name;
size_t *dynv;
struct dso *next, *prev;
Phdr *phdr;
int phnum;
size_t phentsize;
Sym *syms;
Elf_Symndx *hashtab;
uint32_t *ghashtab;
int16_t *versym;
char *strings;
struct dso *syms_next, *lazy_next;
size_t *lazy, lazy_cnt;
unsigned char *map;
size_t map_len;
dev_t dev;
ino_t ino;
char relocated;
char constructed;
char kernel_mapped;
struct dso **deps, *needed_by;
char *rpath_orig, *rpath;
struct tls_module tls;
size_t tls_id;
2014-03-25 12:13:27 +00:00
size_t relro_start, relro_end;
uintptr_t *new_dtv;
unsigned char *new_tls;
make all objects used with atomic operations volatile the memory model we use internally for atomics permits plain loads of values which may be subject to concurrent modification without requiring that a special load function be used. since a compiler is free to make transformations that alter the number of loads or the way in which loads are performed, the compiler is theoretically free to break this usage. the most obvious concern is with atomic cas constructs: something of the form tmp=*p;a_cas(p,tmp,f(tmp)); could be transformed to a_cas(p,*p,f(*p)); where the latter is intended to show multiple loads of *p whose resulting values might fail to be equal; this would break the atomicity of the whole operation. but even more fundamental breakage is possible. with the changes being made now, objects that may be modified by atomics are modeled as volatile, and the atomic operations performed on them by other threads are modeled as asynchronous stores by hardware which happens to be acting on the request of another thread. such modeling of course does not itself address memory synchronization between cores/cpus, but that aspect was already handled. this all seems less than ideal, but it's the best we can do without mandating a C11 compiler and using the C11 model for atomics. in the case of pthread_once_t, the ABI type of the underlying object is not volatile-qualified. so we are assuming that accessing the object through a volatile-qualified lvalue via casts yields volatile access semantics. the language of the C standard is somewhat unclear on this matter, but this is an assumption the linux kernel also makes, and seems to be the correct interpretation of the standard.
2015-03-04 03:50:02 +00:00
volatile int new_dtv_idx, new_tls_idx;
struct td_index *td_index;
struct dso *fini_next;
char *shortname;
#if DL_FDPIC
unsigned char *base;
#else
struct fdpic_loadmap *loadmap;
#endif
struct funcdesc {
void *addr;
size_t *got;
} *funcdescs;
size_t *got;
char buf[];
};
struct symdef {
Sym *sym;
struct dso *dso;
};
static struct builtin_tls {
char c;
struct pthread pt;
void *space[16];
} builtin_tls[1];
#define MIN_TLS_ALIGN offsetof(struct builtin_tls, pt)
reprocess all libc/ldso symbolic relocations in dynamic linking stage 3 commit f3ddd173806fd5c60b3f034528ca24542aecc5b9 introduced early relocations and subsequent reprocessing as part of the dynamic linker bootstrap overhaul, to allow use of arbitrary libc functions before the main application and libraries are loaded, but only reprocessed GOT/PLT relocation types. commit c093e2e8201524db0d638920e76bcb6b1d925f3a added reprocessing of non-GOT/PLT relocations to fix an actual regression that was observed on powerpc, but only for RELA format tables with out-of-line addends. REL table (inline addends at the relocation address) reprocessing is trickier because the first relocation pass clobbers the addends. this patch extends symbolic relocation reprocessing for libc/ldso to support all relocation types, whether REL or RELA format tables are used. it is believed not to alter behavior on any existing archs for the current dynamic linker and libc code. the motivations for this change are consistency and future-proofing. it ensures that behavior does not differ depending on whether REL or RELA tables are used, which could lead to undetected arch-specific bugs. it also ensures that, if in the future code depending on additional relocation types is added to libc.so, either at the source level or as part of the compiler runtime that gets pulled in (for example, soft-float with TLS for fenv), the new code will work properly. the implementation concept is simple: stage 2 of the dynamic linker counts the number of symbolic relocations in the libc/ldso REL table and allocates a VLA to save their addends into; stage 3 then uses the saved addends in place of the inline ones which were clobbered. for stack safety, a hard limit (currently 4k) is imposed on the number of such addends; this should be a couple orders of magnitude larger than the actual need. this number is not a runtime variable that could break fail-safety; it is constant for a given libc.so build.
2015-05-26 03:33:59 +00:00
#define ADDEND_LIMIT 4096
static size_t *saved_addends, *apply_addends_to;
static struct dso ldso;
static struct dso *head, *tail, *fini_head, *syms_tail, *lazy_head;
static char *env_path, *sys_path;
static unsigned long long gencnt;
static int runtime;
static int ldd_mode;
static int ldso_fail;
static int noload;
static jmp_buf *rtld_fail;
static pthread_rwlock_t lock;
static struct debug debug;
static struct tls_module *tls_tail;
static size_t tls_cnt, tls_offset, tls_align = MIN_TLS_ALIGN;
static size_t static_tls_cnt;
static pthread_mutex_t init_fini_lock = { ._m_type = PTHREAD_MUTEX_RECURSIVE };
static struct fdpic_loadmap *app_loadmap;
static struct fdpic_dummy_loadmap app_dummy_loadmap;
static struct dso *const nodeps_dummy;
struct debug *_dl_debug_addr = &debug;
extern hidden int __malloc_replaced;
hidden void (*const __init_array_start)(void)=0, (*const __fini_array_start)(void)=0;
remove undef weak refs to init/fini array symbols in libc.so commit ad1cd43a86645ba2d4f7c8747240452a349d6bc1 eliminated preprocessor-level omission of references to the init/fini array symbols from object files going into libc.so. the references are weak, and the intent was that the linker would resolve them to zero in libc.so, but instead it leaves undefined references that could be satisfied at runtime. normally these references would be harmless, since the code using them does not even get executed, but some older binutils versions produce a linking error: when linking a program against libc.so, ld first tries to use the hidden init/fini array symbols produced by the linker script to satisfy the references in libc.so, then produces an error because the definitions are hidden. ideally ld would have already provided definitions of these symbols when linking libc.so, but the linker script for -shared omits them. to avoid this situation, the dynamic linker now provides its own dummy definitions of the init/fini array symbols for libc.so. since they are hidden, everything binds at ld time and no references remain in the dynamic symbol table. with modern binutils and --gc-sections, both the dummy empty array objects and the code referencing them get dropped at link time, anyway. the _init and _fini symbols are also switched back to using weak definitions rather than weak references since the latter behave somewhat problematically in general, and the weak definition approach was known to work well.
2015-11-20 01:28:08 +00:00
extern hidden void (*const __init_array_end)(void), (*const __fini_array_end)(void);
remove undef weak refs to init/fini array symbols in libc.so commit ad1cd43a86645ba2d4f7c8747240452a349d6bc1 eliminated preprocessor-level omission of references to the init/fini array symbols from object files going into libc.so. the references are weak, and the intent was that the linker would resolve them to zero in libc.so, but instead it leaves undefined references that could be satisfied at runtime. normally these references would be harmless, since the code using them does not even get executed, but some older binutils versions produce a linking error: when linking a program against libc.so, ld first tries to use the hidden init/fini array symbols produced by the linker script to satisfy the references in libc.so, then produces an error because the definitions are hidden. ideally ld would have already provided definitions of these symbols when linking libc.so, but the linker script for -shared omits them. to avoid this situation, the dynamic linker now provides its own dummy definitions of the init/fini array symbols for libc.so. since they are hidden, everything binds at ld time and no references remain in the dynamic symbol table. with modern binutils and --gc-sections, both the dummy empty array objects and the code referencing them get dropped at link time, anyway. the _init and _fini symbols are also switched back to using weak definitions rather than weak references since the latter behave somewhat problematically in general, and the weak definition approach was known to work well.
2015-11-20 01:28:08 +00:00
weak_alias(__init_array_start, __init_array_end);
weak_alias(__fini_array_start, __fini_array_end);
static int dl_strcmp(const char *l, const char *r)
{
for (; *l==*r && *l; l++, r++);
return *(unsigned char *)l - *(unsigned char *)r;
}
#define strcmp(l,r) dl_strcmp(l,r)
/* Compute load address for a virtual address in a given dso. */
#if DL_FDPIC
static void *laddr(const struct dso *p, size_t v)
{
size_t j=0;
if (!p->loadmap) return p->base + v;
for (j=0; v-p->loadmap->segs[j].p_vaddr >= p->loadmap->segs[j].p_memsz; j++);
return (void *)(v - p->loadmap->segs[j].p_vaddr + p->loadmap->segs[j].addr);
}
static void *laddr_pg(const struct dso *p, size_t v)
{
size_t j=0;
size_t pgsz = PAGE_SIZE;
if (!p->loadmap) return p->base + v;
for (j=0; ; j++) {
size_t a = p->loadmap->segs[j].p_vaddr;
size_t b = a + p->loadmap->segs[j].p_memsz;
a &= -pgsz;
b += pgsz-1;
b &= -pgsz;
if (v-a<b-a) break;
}
return (void *)(v - p->loadmap->segs[j].p_vaddr + p->loadmap->segs[j].addr);
}
#define fpaddr(p, v) ((void (*)())&(struct funcdesc){ \
laddr(p, v), (p)->got })
#else
#define laddr(p, v) (void *)((p)->base + (v))
#define laddr_pg(p, v) laddr(p, v)
#define fpaddr(p, v) ((void (*)())laddr(p, v))
#endif
static void decode_vec(size_t *v, size_t *a, size_t cnt)
{
size_t i;
for (i=0; i<cnt; i++) a[i] = 0;
for (; v[0]; v+=2) if (v[0]-1<cnt-1) {
a[0] |= 1UL<<v[0];
a[v[0]] = v[1];
}
}
static int search_vec(size_t *v, size_t *r, size_t key)
{
for (; v[0]!=key; v+=2)
if (!v[0]) return 0;
*r = v[1];
return 1;
}
static uint32_t sysv_hash(const char *s0)
{
const unsigned char *s = (void *)s0;
uint_fast32_t h = 0;
while (*s) {
h = 16*h + *s++;
h ^= h>>24 & 0xf0;
}
return h & 0xfffffff;
}
static uint32_t gnu_hash(const char *s0)
{
const unsigned char *s = (void *)s0;
uint_fast32_t h = 5381;
for (; *s; s++)
h += h*32 + *s;
return h;
}
static Sym *sysv_lookup(const char *s, uint32_t h, struct dso *dso)
{
size_t i;
2012-08-05 06:38:35 +00:00
Sym *syms = dso->syms;
Elf_Symndx *hashtab = dso->hashtab;
2012-08-05 06:38:35 +00:00
char *strings = dso->strings;
for (i=hashtab[2+h%hashtab[0]]; i; i=hashtab[2+hashtab[0]+i]) {
if ((!dso->versym || dso->versym[i] >= 0)
&& (!strcmp(s, strings+syms[i].st_name)))
return syms+i;
}
return 0;
}
static Sym *gnu_lookup(uint32_t h1, uint32_t *hashtab, struct dso *dso, const char *s)
{
uint32_t nbuckets = hashtab[0];
uint32_t *buckets = hashtab + 4 + hashtab[2]*(sizeof(size_t)/4);
uint32_t i = buckets[h1 % nbuckets];
if (!i) return 0;
uint32_t *hashval = buckets + nbuckets + (i - hashtab[1]);
for (h1 |= 1; ; i++) {
uint32_t h2 = *hashval++;
if ((h1 == (h2|1)) && (!dso->versym || dso->versym[i] >= 0)
&& !strcmp(s, dso->strings + dso->syms[i].st_name))
return dso->syms+i;
if (h2 & 1) break;
}
return 0;
}
static Sym *gnu_lookup_filtered(uint32_t h1, uint32_t *hashtab, struct dso *dso, const char *s, uint32_t fofs, size_t fmask)
{
const size_t *bloomwords = (const void *)(hashtab+4);
size_t f = bloomwords[fofs & (hashtab[2]-1)];
if (!(f & fmask)) return 0;
f >>= (h1 >> hashtab[3]) % (8 * sizeof f);
if (!(f & 1)) return 0;
return gnu_lookup(h1, hashtab, dso, s);
}
#define OK_TYPES (1<<STT_NOTYPE | 1<<STT_OBJECT | 1<<STT_FUNC | 1<<STT_COMMON | 1<<STT_TLS)
#define OK_BINDS (1<<STB_GLOBAL | 1<<STB_WEAK | 1<<STB_GNU_UNIQUE)
fix regression in mips dynamic linker this issue caused the address of functions in shared libraries to resolve to their PLT thunks in the main program rather than their correct addresses. it was observed causing crashes, though the mechanism of the crash was not thoroughly investigated. since the issue is very subtle, it calls for some explanation: on all well-behaved archs, GOT entries that belong to the PLT use a special relocation type, typically called JMP_SLOT, so that the dynamic linker can avoid having the jump destinations for the PLT resolve to PLT thunks themselves (they also provide a definition for the symbol, which must be used whenever the address of the function is taken so that all DSOs see the same address). however, the traditional mips PIC ABI lacked such a JMP_SLOT relocation type, presumably because, due to the way PIC works, the address of the PLT thunk was never needed and could always be ignored. prior to commit adf94c19666e687a728bbf398f9a88ea4ea19996, the mips version of reloc.h contained a hack that caused all symbol lookups to be treated like JMP_SLOT, inhibiting undefined symbols from ever being used to resolve symbolic relocations. this hack goes all the way back to commit babf820180368f00742ec65b2050a82380d7c542, when the mips dynamic linker was first made usable. during the recent refactoring to eliminate arch-specific relocation processing (commit adf94c19666e687a728bbf398f9a88ea4ea19996), this hack was overlooked and no equivalent functionality was provided in the new code. fixing the problem is not as simple as adding back an equivalent hack, since there is now also a "non-PIC ABI" that can be used for the main executable, which actually does use a PLT. the closest thing to official documentation I could find for this ABI is nonpic.txt, attached to Message-ID: 20080701202236.GA1534@caradoc.them.org, which can be found in the gcc mailing list archives and elsewhere. per this document, undefined symbols corresponding to PLT thunks have the STO_MIPS_PLT bit set in the symbol's st_other field. thus, I have added an arch-specific rule for mips, applied at the find_sym level rather than the relocation level, to reject undefined symbols with the STO_MIPS_PLT bit clear. the previous hack of treating all mips relocations as JMP_SLOT-like, rather than rejecting the unwanted symbols in find_sym, probably also caused dlsym to wrongly return PLT thunks in place of the correct address of a function under at least some conditions. this should now be fixed, at least for global-scope symbol lookups.
2014-06-30 05:18:14 +00:00
#ifndef ARCH_SYM_REJECT_UND
#define ARCH_SYM_REJECT_UND(s) 0
#endif
static struct symdef find_sym(struct dso *dso, const char *s, int need_def)
{
uint32_t h = 0, gh = gnu_hash(s), gho = gh / (8*sizeof(size_t)), *ght;
size_t ghm = 1ul << gh % (8*sizeof(size_t));
struct symdef def = {0};
rework ldso handling of global symbol table for consistency when loading libraries with dlopen, the caller can request that the library's symbols become part of the global symbol table, or that they only be used for resolving relocations in the loaded library and its dependencies. in the latter case, a subsequent dlopen of the same library can upgrade it to global status. previously, if a library was upgraded from local to global mode, its symbols entered the symbol lookup search order at the point where the library was originally loaded. this means that a new call to dlopen could change the value of a symbol that already had a visible definition, an inconsistency which applications could observe. POSIX is unclear whether this should happen or whether it's permitted to happen, but the resolution of Austin Group issue #982 made it formally unspecified. with this patch, a library whose mode is upgraded from local to global enters the symbol lookup order at the point where it was made global, so that symbol resolution before and after the upgrade are consistent. in order to implement this change, the per-dso global flag is replaced with a separate set of linked-list pointers for participation in the global symbol table. this permits the order of dso objects for symbol resolution to differ from the order used for iteration of all loaded libraries. it also improves performance of find_sym, by avoiding a branch per iteration and skipping, and especially in the case where many non-global libraries have been loaded, by allowing the loop to skip over them entirely. logic for temporarily adding non-global libraries to the symbol table for relocation purposes is also mildly simplified.
2017-03-13 01:03:05 +00:00
for (; dso; dso=dso->syms_next) {
Sym *sym;
if ((ght = dso->ghashtab)) {
sym = gnu_lookup_filtered(gh, ght, dso, s, gho, ghm);
} else {
if (!h) h = sysv_hash(s);
sym = sysv_lookup(s, h, dso);
}
if (!sym) continue;
if (!sym->st_shndx)
fix regression in mips dynamic linker this issue caused the address of functions in shared libraries to resolve to their PLT thunks in the main program rather than their correct addresses. it was observed causing crashes, though the mechanism of the crash was not thoroughly investigated. since the issue is very subtle, it calls for some explanation: on all well-behaved archs, GOT entries that belong to the PLT use a special relocation type, typically called JMP_SLOT, so that the dynamic linker can avoid having the jump destinations for the PLT resolve to PLT thunks themselves (they also provide a definition for the symbol, which must be used whenever the address of the function is taken so that all DSOs see the same address). however, the traditional mips PIC ABI lacked such a JMP_SLOT relocation type, presumably because, due to the way PIC works, the address of the PLT thunk was never needed and could always be ignored. prior to commit adf94c19666e687a728bbf398f9a88ea4ea19996, the mips version of reloc.h contained a hack that caused all symbol lookups to be treated like JMP_SLOT, inhibiting undefined symbols from ever being used to resolve symbolic relocations. this hack goes all the way back to commit babf820180368f00742ec65b2050a82380d7c542, when the mips dynamic linker was first made usable. during the recent refactoring to eliminate arch-specific relocation processing (commit adf94c19666e687a728bbf398f9a88ea4ea19996), this hack was overlooked and no equivalent functionality was provided in the new code. fixing the problem is not as simple as adding back an equivalent hack, since there is now also a "non-PIC ABI" that can be used for the main executable, which actually does use a PLT. the closest thing to official documentation I could find for this ABI is nonpic.txt, attached to Message-ID: 20080701202236.GA1534@caradoc.them.org, which can be found in the gcc mailing list archives and elsewhere. per this document, undefined symbols corresponding to PLT thunks have the STO_MIPS_PLT bit set in the symbol's st_other field. thus, I have added an arch-specific rule for mips, applied at the find_sym level rather than the relocation level, to reject undefined symbols with the STO_MIPS_PLT bit clear. the previous hack of treating all mips relocations as JMP_SLOT-like, rather than rejecting the unwanted symbols in find_sym, probably also caused dlsym to wrongly return PLT thunks in place of the correct address of a function under at least some conditions. this should now be fixed, at least for global-scope symbol lookups.
2014-06-30 05:18:14 +00:00
if (need_def || (sym->st_info&0xf) == STT_TLS
|| ARCH_SYM_REJECT_UND(sym))
continue;
if (!sym->st_value)
if ((sym->st_info&0xf) != STT_TLS)
continue;
if (!(1<<(sym->st_info&0xf) & OK_TYPES)) continue;
if (!(1<<(sym->st_info>>4) & OK_BINDS)) continue;
def.sym = sym;
def.dso = dso;
break;
}
return def;
}
static void do_relocs(struct dso *dso, size_t *rel, size_t rel_size, size_t stride)
{
unsigned char *base = dso->base;
Sym *syms = dso->syms;
char *strings = dso->strings;
Sym *sym;
const char *name;
void *ctx;
int type;
int sym_index;
struct symdef def;
size_t *reloc_addr;
size_t sym_val;
size_t tls_val;
size_t addend;
reprocess all libc/ldso symbolic relocations in dynamic linking stage 3 commit f3ddd173806fd5c60b3f034528ca24542aecc5b9 introduced early relocations and subsequent reprocessing as part of the dynamic linker bootstrap overhaul, to allow use of arbitrary libc functions before the main application and libraries are loaded, but only reprocessed GOT/PLT relocation types. commit c093e2e8201524db0d638920e76bcb6b1d925f3a added reprocessing of non-GOT/PLT relocations to fix an actual regression that was observed on powerpc, but only for RELA format tables with out-of-line addends. REL table (inline addends at the relocation address) reprocessing is trickier because the first relocation pass clobbers the addends. this patch extends symbolic relocation reprocessing for libc/ldso to support all relocation types, whether REL or RELA format tables are used. it is believed not to alter behavior on any existing archs for the current dynamic linker and libc code. the motivations for this change are consistency and future-proofing. it ensures that behavior does not differ depending on whether REL or RELA tables are used, which could lead to undetected arch-specific bugs. it also ensures that, if in the future code depending on additional relocation types is added to libc.so, either at the source level or as part of the compiler runtime that gets pulled in (for example, soft-float with TLS for fenv), the new code will work properly. the implementation concept is simple: stage 2 of the dynamic linker counts the number of symbolic relocations in the libc/ldso REL table and allocates a VLA to save their addends into; stage 3 then uses the saved addends in place of the inline ones which were clobbered. for stack safety, a hard limit (currently 4k) is imposed on the number of such addends; this should be a couple orders of magnitude larger than the actual need. this number is not a runtime variable that could break fail-safety; it is constant for a given libc.so build.
2015-05-26 03:33:59 +00:00
int skip_relative = 0, reuse_addends = 0, save_slot = 0;
if (dso == &ldso) {
/* Only ldso's REL table needs addend saving/reuse. */
if (rel == apply_addends_to)
reuse_addends = 1;
skip_relative = 1;
}
for (; rel_size; rel+=stride, rel_size-=stride*sizeof(size_t)) {
if (skip_relative && IS_RELATIVE(rel[1], dso->syms)) continue;
type = R_TYPE(rel[1]);
if (type == REL_NONE) continue;
reloc_addr = laddr(dso, rel[0]);
if (stride > 2) {
addend = rel[2];
} else if (type==REL_GOT || type==REL_PLT|| type==REL_COPY) {
addend = 0;
} else if (reuse_addends) {
/* Save original addend in stage 2 where the dso
* chain consists of just ldso; otherwise read back
* saved addend since the inline one was clobbered. */
if (head==&ldso)
saved_addends[save_slot] = *reloc_addr;
addend = saved_addends[save_slot++];
} else {
addend = *reloc_addr;
}
sym_index = R_SYM(rel[1]);
if (sym_index) {
sym = syms + sym_index;
name = strings + sym->st_name;
rework ldso handling of global symbol table for consistency when loading libraries with dlopen, the caller can request that the library's symbols become part of the global symbol table, or that they only be used for resolving relocations in the loaded library and its dependencies. in the latter case, a subsequent dlopen of the same library can upgrade it to global status. previously, if a library was upgraded from local to global mode, its symbols entered the symbol lookup search order at the point where the library was originally loaded. this means that a new call to dlopen could change the value of a symbol that already had a visible definition, an inconsistency which applications could observe. POSIX is unclear whether this should happen or whether it's permitted to happen, but the resolution of Austin Group issue #982 made it formally unspecified. with this patch, a library whose mode is upgraded from local to global enters the symbol lookup order at the point where it was made global, so that symbol resolution before and after the upgrade are consistent. in order to implement this change, the per-dso global flag is replaced with a separate set of linked-list pointers for participation in the global symbol table. this permits the order of dso objects for symbol resolution to differ from the order used for iteration of all loaded libraries. it also improves performance of find_sym, by avoiding a branch per iteration and skipping, and especially in the case where many non-global libraries have been loaded, by allowing the loop to skip over them entirely. logic for temporarily adding non-global libraries to the symbol table for relocation purposes is also mildly simplified.
2017-03-13 01:03:05 +00:00
ctx = type==REL_COPY ? head->syms_next : head;
def = (sym->st_info&0xf) == STT_SECTION
? (struct symdef){ .dso = dso, .sym = sym }
: find_sym(ctx, name, type==REL_PLT);
if (!def.sym && (sym->st_shndx != SHN_UNDEF
|| sym->st_info>>4 != STB_WEAK)) {
if (dso->lazy && (type==REL_PLT || type==REL_GOT)) {
dso->lazy[3*dso->lazy_cnt+0] = rel[0];
dso->lazy[3*dso->lazy_cnt+1] = rel[1];
dso->lazy[3*dso->lazy_cnt+2] = addend;
dso->lazy_cnt++;
continue;
}
error("Error relocating %s: %s: symbol not found",
dso->name, name);
if (runtime) longjmp(*rtld_fail, 1);
continue;
}
} else {
sym = 0;
def.sym = 0;
def.dso = dso;
}
sym_val = def.sym ? (size_t)laddr(def.dso, def.sym->st_value) : 0;
tls_val = def.sym ? def.sym->st_value : 0;
if ((type == REL_TPOFF || type == REL_TPOFF_NEG)
&& runtime && def.dso->tls_id > static_tls_cnt) {
error("Error relocating %s: %s: initial-exec TLS "
"resolves to dynamic definition in %s",
dso->name, name, def.dso->name);
longjmp(*rtld_fail, 1);
}
switch(type) {
case REL_NONE:
break;
case REL_OFFSET:
addend -= (size_t)reloc_addr;
case REL_SYMBOLIC:
case REL_GOT:
case REL_PLT:
*reloc_addr = sym_val + addend;
break;
case REL_RELATIVE:
*reloc_addr = (size_t)base + addend;
break;
case REL_SYM_OR_REL:
if (sym) *reloc_addr = sym_val + addend;
else *reloc_addr = (size_t)base + addend;
break;
case REL_COPY:
memcpy(reloc_addr, (void *)sym_val, sym->st_size);
break;
case REL_OFFSET32:
*(uint32_t *)reloc_addr = sym_val + addend
- (size_t)reloc_addr;
break;
case REL_FUNCDESC:
*reloc_addr = def.sym ? (size_t)(def.dso->funcdescs
+ (def.sym - def.dso->syms)) : 0;
break;
case REL_FUNCDESC_VAL:
if ((sym->st_info&0xf) == STT_SECTION) *reloc_addr += sym_val;
else *reloc_addr = sym_val;
reloc_addr[1] = def.sym ? (size_t)def.dso->got : 0;
break;
case REL_DTPMOD:
*reloc_addr = def.dso->tls_id;
break;
case REL_DTPOFF:
*reloc_addr = tls_val + addend - DTP_OFFSET;
break;
#ifdef TLS_ABOVE_TP
case REL_TPOFF:
*reloc_addr = tls_val + def.dso->tls.offset + TPOFF_K + addend;
break;
#else
case REL_TPOFF:
*reloc_addr = tls_val - def.dso->tls.offset + addend;
break;
case REL_TPOFF_NEG:
*reloc_addr = def.dso->tls.offset - tls_val + addend;
break;
#endif
case REL_TLSDESC:
if (stride<3) addend = reloc_addr[1];
if (runtime && def.dso->tls_id > static_tls_cnt) {
struct td_index *new = malloc(sizeof *new);
if (!new) {
error(
"Error relocating %s: cannot allocate TLSDESC for %s",
dso->name, sym ? name : "(local)" );
longjmp(*rtld_fail, 1);
}
new->next = dso->td_index;
dso->td_index = new;
new->args[0] = def.dso->tls_id;
new->args[1] = tls_val + addend - DTP_OFFSET;
reloc_addr[0] = (size_t)__tlsdesc_dynamic;
reloc_addr[1] = (size_t)new;
} else {
reloc_addr[0] = (size_t)__tlsdesc_static;
#ifdef TLS_ABOVE_TP
reloc_addr[1] = tls_val + def.dso->tls.offset
+ TPOFF_K + addend;
#else
reloc_addr[1] = tls_val - def.dso->tls.offset
+ addend;
#endif
}
#ifdef TLSDESC_BACKWARDS
/* Some archs (32-bit ARM at least) invert the order of
* the descriptor members. Fix them up here. */
size_t tmp = reloc_addr[0];
reloc_addr[0] = reloc_addr[1];
reloc_addr[1] = tmp;
#endif
break;
default:
error("Error relocating %s: unsupported relocation type %d",
dso->name, type);
if (runtime) longjmp(*rtld_fail, 1);
continue;
}
}
}
static void redo_lazy_relocs()
{
struct dso *p = lazy_head, *next;
lazy_head = 0;
for (; p; p=next) {
next = p->lazy_next;
size_t size = p->lazy_cnt*3*sizeof(size_t);
p->lazy_cnt = 0;
do_relocs(p, p->lazy, size, 3);
if (p->lazy_cnt) {
p->lazy_next = lazy_head;
lazy_head = p;
} else {
free(p->lazy);
p->lazy = 0;
p->lazy_next = 0;
}
}
}
/* A huge hack: to make up for the wastefulness of shared libraries
* needing at least a page of dirty memory even if they have no global
* data, we reclaim the gaps at the beginning and end of writable maps
* and "donate" them to the heap. */
2014-03-25 12:13:27 +00:00
static void reclaim(struct dso *dso, size_t start, size_t end)
{
2014-03-25 12:13:27 +00:00
if (start >= dso->relro_start && start < dso->relro_end) start = dso->relro_end;
if (end >= dso->relro_start && end < dso->relro_end) end = dso->relro_start;
if (start >= end) return;
char *base = laddr_pg(dso, start);
__malloc_donate(base, base+(end-start));
}
static void reclaim_gaps(struct dso *dso)
{
Phdr *ph = dso->phdr;
size_t phcnt = dso->phnum;
for (; phcnt--; ph=(void *)((char *)ph+dso->phentsize)) {
if (ph->p_type!=PT_LOAD) continue;
if ((ph->p_flags&(PF_R|PF_W))!=(PF_R|PF_W)) continue;
2014-03-25 12:13:27 +00:00
reclaim(dso, ph->p_vaddr & -PAGE_SIZE, ph->p_vaddr);
reclaim(dso, ph->p_vaddr+ph->p_memsz,
ph->p_vaddr+ph->p_memsz+PAGE_SIZE-1 & -PAGE_SIZE);
}
}
static void *mmap_fixed(void *p, size_t n, int prot, int flags, int fd, off_t off)
{
static int no_map_fixed;
char *q;
if (!no_map_fixed) {
q = mmap(p, n, prot, flags|MAP_FIXED, fd, off);
if (!DL_NOMMU_SUPPORT || q != MAP_FAILED || errno != EINVAL)
return q;
no_map_fixed = 1;
}
/* Fallbacks for MAP_FIXED failure on NOMMU kernels. */
if (flags & MAP_ANONYMOUS) {
memset(p, 0, n);
return p;
}
ssize_t r;
if (lseek(fd, off, SEEK_SET) < 0) return MAP_FAILED;
for (q=p; n; q+=r, off+=r, n-=r) {
r = read(fd, q, n);
if (r < 0 && errno != EINTR) return MAP_FAILED;
if (!r) {
memset(q, 0, n);
break;
}
}
return p;
}
static void unmap_library(struct dso *dso)
{
if (dso->loadmap) {
size_t i;
for (i=0; i<dso->loadmap->nsegs; i++) {
if (!dso->loadmap->segs[i].p_memsz)
continue;
munmap((void *)dso->loadmap->segs[i].addr,
dso->loadmap->segs[i].p_memsz);
}
free(dso->loadmap);
} else if (dso->map && dso->map_len) {
munmap(dso->map, dso->map_len);
}
}
static void *map_library(int fd, struct dso *dso)
{
Ehdr buf[(896+sizeof(Ehdr))/sizeof(Ehdr)];
void *allocated_buf=0;
size_t phsize;
size_t addr_min=SIZE_MAX, addr_max=0, map_len;
size_t this_min, this_max;
size_t nsegs = 0;
off_t off_start;
Ehdr *eh;
Phdr *ph, *ph0;
unsigned prot;
unsigned char *map=MAP_FAILED, *base;
size_t dyn=0;
size_t tls_image=0;
size_t i;
ssize_t l = read(fd, buf, sizeof buf);
eh = buf;
if (l<0) return 0;
if (l<sizeof *eh || (eh->e_type != ET_DYN && eh->e_type != ET_EXEC))
goto noexec;
phsize = eh->e_phentsize * eh->e_phnum;
if (phsize > sizeof buf - sizeof *eh) {
allocated_buf = malloc(phsize);
if (!allocated_buf) return 0;
l = pread(fd, allocated_buf, phsize, eh->e_phoff);
if (l < 0) goto error;
if (l != phsize) goto noexec;
ph = ph0 = allocated_buf;
} else if (eh->e_phoff + phsize > l) {
l = pread(fd, buf+1, phsize, eh->e_phoff);
if (l < 0) goto error;
if (l != phsize) goto noexec;
ph = ph0 = (void *)(buf + 1);
} else {
ph = ph0 = (void *)((char *)buf + eh->e_phoff);
}
for (i=eh->e_phnum; i; i--, ph=(void *)((char *)ph+eh->e_phentsize)) {
if (ph->p_type == PT_DYNAMIC) {
dyn = ph->p_vaddr;
} else if (ph->p_type == PT_TLS) {
tls_image = ph->p_vaddr;
dso->tls.align = ph->p_align;
dso->tls.len = ph->p_filesz;
dso->tls.size = ph->p_memsz;
2014-03-25 12:13:27 +00:00
} else if (ph->p_type == PT_GNU_RELRO) {
dso->relro_start = ph->p_vaddr & -PAGE_SIZE;
dso->relro_end = (ph->p_vaddr + ph->p_memsz) & -PAGE_SIZE;
} else if (ph->p_type == PT_GNU_STACK) {
if (!runtime && ph->p_memsz > __default_stacksize) {
__default_stacksize =
ph->p_memsz < DEFAULT_STACK_MAX ?
ph->p_memsz : DEFAULT_STACK_MAX;
}
}
if (ph->p_type != PT_LOAD) continue;
nsegs++;
if (ph->p_vaddr < addr_min) {
addr_min = ph->p_vaddr;
off_start = ph->p_offset;
prot = (((ph->p_flags&PF_R) ? PROT_READ : 0) |
((ph->p_flags&PF_W) ? PROT_WRITE: 0) |
((ph->p_flags&PF_X) ? PROT_EXEC : 0));
}
if (ph->p_vaddr+ph->p_memsz > addr_max) {
addr_max = ph->p_vaddr+ph->p_memsz;
}
}
if (!dyn) goto noexec;
if (DL_FDPIC && !(eh->e_flags & FDPIC_CONSTDISP_FLAG)) {
dso->loadmap = calloc(1, sizeof *dso->loadmap
+ nsegs * sizeof *dso->loadmap->segs);
if (!dso->loadmap) goto error;
dso->loadmap->nsegs = nsegs;
for (ph=ph0, i=0; i<nsegs; ph=(void *)((char *)ph+eh->e_phentsize)) {
if (ph->p_type != PT_LOAD) continue;
prot = (((ph->p_flags&PF_R) ? PROT_READ : 0) |
((ph->p_flags&PF_W) ? PROT_WRITE: 0) |
((ph->p_flags&PF_X) ? PROT_EXEC : 0));
map = mmap(0, ph->p_memsz + (ph->p_vaddr & PAGE_SIZE-1),
prot, MAP_PRIVATE,
fd, ph->p_offset & -PAGE_SIZE);
if (map == MAP_FAILED) {
unmap_library(dso);
goto error;
}
dso->loadmap->segs[i].addr = (size_t)map +
(ph->p_vaddr & PAGE_SIZE-1);
dso->loadmap->segs[i].p_vaddr = ph->p_vaddr;
dso->loadmap->segs[i].p_memsz = ph->p_memsz;
i++;
if (prot & PROT_WRITE) {
size_t brk = (ph->p_vaddr & PAGE_SIZE-1)
+ ph->p_filesz;
size_t pgbrk = brk + PAGE_SIZE-1 & -PAGE_SIZE;
size_t pgend = brk + ph->p_memsz - ph->p_filesz
+ PAGE_SIZE-1 & -PAGE_SIZE;
if (pgend > pgbrk && mmap_fixed(map+pgbrk,
pgend-pgbrk, prot,
MAP_PRIVATE|MAP_FIXED|MAP_ANONYMOUS,
-1, off_start) == MAP_FAILED)
goto error;
memset(map + brk, 0, pgbrk-brk);
}
}
map = (void *)dso->loadmap->segs[0].addr;
map_len = 0;
goto done_mapping;
}
addr_max += PAGE_SIZE-1;
addr_max &= -PAGE_SIZE;
addr_min &= -PAGE_SIZE;
off_start &= -PAGE_SIZE;
map_len = addr_max - addr_min + off_start;
/* The first time, we map too much, possibly even more than
* the length of the file. This is okay because we will not
* use the invalid part; we just need to reserve the right
* amount of virtual address space to map over later. */
map = DL_NOMMU_SUPPORT
? mmap((void *)addr_min, map_len, PROT_READ|PROT_WRITE|PROT_EXEC,
MAP_PRIVATE|MAP_ANONYMOUS, -1, 0)
: mmap((void *)addr_min, map_len, prot,
MAP_PRIVATE, fd, off_start);
if (map==MAP_FAILED) goto error;
dso->map = map;
dso->map_len = map_len;
/* If the loaded file is not relocatable and the requested address is
* not available, then the load operation must fail. */
if (eh->e_type != ET_DYN && addr_min && map!=(void *)addr_min) {
errno = EBUSY;
goto error;
}
base = map - addr_min;
dso->phdr = 0;
dso->phnum = 0;
for (ph=ph0, i=eh->e_phnum; i; i--, ph=(void *)((char *)ph+eh->e_phentsize)) {
if (ph->p_type != PT_LOAD) continue;
/* Check if the programs headers are in this load segment, and
* if so, record the address for use by dl_iterate_phdr. */
if (!dso->phdr && eh->e_phoff >= ph->p_offset
&& eh->e_phoff+phsize <= ph->p_offset+ph->p_filesz) {
dso->phdr = (void *)(base + ph->p_vaddr
+ (eh->e_phoff-ph->p_offset));
dso->phnum = eh->e_phnum;
dso->phentsize = eh->e_phentsize;
}
this_min = ph->p_vaddr & -PAGE_SIZE;
this_max = ph->p_vaddr+ph->p_memsz+PAGE_SIZE-1 & -PAGE_SIZE;
off_start = ph->p_offset & -PAGE_SIZE;
prot = (((ph->p_flags&PF_R) ? PROT_READ : 0) |
((ph->p_flags&PF_W) ? PROT_WRITE: 0) |
((ph->p_flags&PF_X) ? PROT_EXEC : 0));
/* Reuse the existing mapping for the lowest-address LOAD */
if ((ph->p_vaddr & -PAGE_SIZE) != addr_min || DL_NOMMU_SUPPORT)
if (mmap_fixed(base+this_min, this_max-this_min, prot, MAP_PRIVATE|MAP_FIXED, fd, off_start) == MAP_FAILED)
goto error;
if (ph->p_memsz > ph->p_filesz && (ph->p_flags&PF_W)) {
size_t brk = (size_t)base+ph->p_vaddr+ph->p_filesz;
size_t pgbrk = brk+PAGE_SIZE-1 & -PAGE_SIZE;
memset((void *)brk, 0, pgbrk-brk & PAGE_SIZE-1);
if (pgbrk-(size_t)base < this_max && mmap_fixed((void *)pgbrk, (size_t)base+this_max-pgbrk, prot, MAP_PRIVATE|MAP_FIXED|MAP_ANONYMOUS, -1, 0) == MAP_FAILED)
goto error;
}
}
2011-06-29 04:29:08 +00:00
for (i=0; ((size_t *)(base+dyn))[i]; i+=2)
if (((size_t *)(base+dyn))[i]==DT_TEXTREL) {
if (mprotect(map, map_len, PROT_READ|PROT_WRITE|PROT_EXEC)
&& errno != ENOSYS)
goto error;
2011-06-29 04:29:08 +00:00
break;
}
done_mapping:
dso->base = base;
dso->dynv = laddr(dso, dyn);
if (dso->tls.size) dso->tls.image = laddr(dso, tls_image);
free(allocated_buf);
return map;
noexec:
errno = ENOEXEC;
error:
if (map!=MAP_FAILED) unmap_library(dso);
free(allocated_buf);
return 0;
}
static int path_open(const char *name, const char *s, char *buf, size_t buf_size)
{
size_t l;
int fd;
for (;;) {
s += strspn(s, ":\n");
l = strcspn(s, ":\n");
if (l-1 >= INT_MAX) return -1;
if (snprintf(buf, buf_size, "%.*s/%s", (int)l, s, name) < buf_size) {
if ((fd = open(buf, O_RDONLY|O_CLOEXEC))>=0) return fd;
switch (errno) {
case ENOENT:
case ENOTDIR:
case EACCES:
case ENAMETOOLONG:
break;
default:
/* Any negative value but -1 will inhibit
* futher path search. */
return -2;
}
}
s += l;
}
}
static int fixup_rpath(struct dso *p, char *buf, size_t buf_size)
{
size_t n, l;
const char *s, *t, *origin;
char *d;
if (p->rpath || !p->rpath_orig) return 0;
if (!strchr(p->rpath_orig, '$')) {
p->rpath = p->rpath_orig;
return 0;
}
n = 0;
s = p->rpath_orig;
while ((t=strchr(s, '$'))) {
if (strncmp(t, "$ORIGIN", 7) && strncmp(t, "${ORIGIN}", 9))
return 0;
s = t+1;
n++;
}
if (n > SSIZE_MAX/PATH_MAX) return 0;
if (p->kernel_mapped) {
/* $ORIGIN searches cannot be performed for the main program
* when it is suid/sgid/AT_SECURE. This is because the
* pathname is under the control of the caller of execve.
* For libraries, however, $ORIGIN can be processed safely
* since the library's pathname came from a trusted source
* (either system paths or a call to dlopen). */
if (libc.secure)
return 0;
l = readlink("/proc/self/exe", buf, buf_size);
if (l == -1) switch (errno) {
case ENOENT:
case ENOTDIR:
case EACCES:
break;
default:
return -1;
}
if (l >= buf_size)
return 0;
buf[l] = 0;
origin = buf;
} else {
origin = p->name;
}
t = strrchr(origin, '/');
if (t) {
l = t-origin;
} else {
/* Normally p->name will always be an absolute or relative
* pathname containing at least one '/' character, but in the
* case where ldso was invoked as a command to execute a
* program in the working directory, app.name may not. Fix. */
origin = ".";
l = 1;
}
/* Disallow non-absolute origins for suid/sgid/AT_SECURE. */
if (libc.secure && *origin != '/')
return 0;
p->rpath = malloc(strlen(p->rpath_orig) + n*l + 1);
if (!p->rpath) return -1;
d = p->rpath;
s = p->rpath_orig;
while ((t=strchr(s, '$'))) {
memcpy(d, s, t-s);
d += t-s;
memcpy(d, origin, l);
d += l;
/* It was determined previously that the '$' is followed
* either by "ORIGIN" or "{ORIGIN}". */
s = t + 7 + 2*(t[1]=='{');
}
strcpy(d, s);
return 0;
}
static void decode_dyn(struct dso *p)
{
size_t dyn[DYN_CNT];
decode_vec(p->dynv, dyn, DYN_CNT);
p->syms = laddr(p, dyn[DT_SYMTAB]);
p->strings = laddr(p, dyn[DT_STRTAB]);
if (dyn[0]&(1<<DT_HASH))
p->hashtab = laddr(p, dyn[DT_HASH]);
if (dyn[0]&(1<<DT_RPATH))
p->rpath_orig = p->strings + dyn[DT_RPATH];
if (dyn[0]&(1<<DT_RUNPATH))
p->rpath_orig = p->strings + dyn[DT_RUNPATH];
if (dyn[0]&(1<<DT_PLTGOT))
p->got = laddr(p, dyn[DT_PLTGOT]);
if (search_vec(p->dynv, dyn, DT_GNU_HASH))
p->ghashtab = laddr(p, *dyn);
if (search_vec(p->dynv, dyn, DT_VERSYM))
p->versym = laddr(p, *dyn);
}
static size_t count_syms(struct dso *p)
{
if (p->hashtab) return p->hashtab[1];
size_t nsym, i;
uint32_t *buckets = p->ghashtab + 4 + (p->ghashtab[2]*sizeof(size_t)/4);
uint32_t *hashval;
for (i = nsym = 0; i < p->ghashtab[0]; i++) {
if (buckets[i] > nsym)
nsym = buckets[i];
}
if (nsym) {
hashval = buckets + p->ghashtab[0] + (nsym - p->ghashtab[1]);
do nsym++;
while (!(*hashval++ & 1));
}
return nsym;
}
static void *dl_mmap(size_t n)
{
void *p;
int prot = PROT_READ|PROT_WRITE, flags = MAP_ANONYMOUS|MAP_PRIVATE;
#ifdef SYS_mmap2
p = (void *)__syscall(SYS_mmap2, 0, n, prot, flags, -1, 0);
#else
p = (void *)__syscall(SYS_mmap, 0, n, prot, flags, -1, 0);
#endif
return p == MAP_FAILED ? 0 : p;
}
static void makefuncdescs(struct dso *p)
{
static int self_done;
size_t nsym = count_syms(p);
size_t i, size = nsym * sizeof(*p->funcdescs);
if (!self_done) {
p->funcdescs = dl_mmap(size);
self_done = 1;
} else {
p->funcdescs = malloc(size);
}
if (!p->funcdescs) {
if (!runtime) a_crash();
error("Error allocating function descriptors for %s", p->name);
longjmp(*rtld_fail, 1);
}
for (i=0; i<nsym; i++) {
if ((p->syms[i].st_info&0xf)==STT_FUNC && p->syms[i].st_shndx) {
p->funcdescs[i].addr = laddr(p, p->syms[i].st_value);
p->funcdescs[i].got = p->got;
} else {
p->funcdescs[i].addr = 0;
p->funcdescs[i].got = 0;
}
}
}
static struct dso *load_library(const char *name, struct dso *needed_by)
{
char buf[2*NAME_MAX+2];
const char *pathname;
unsigned char *map;
struct dso *p, temp_dso = {0};
int fd;
struct stat st;
size_t alloc_size;
int n_th = 0;
int is_self = 0;
if (!*name) {
errno = EINVAL;
return 0;
}
/* Catch and block attempts to reload the implementation itself */
if (name[0]=='l' && name[1]=='i' && name[2]=='b') {
static const char reserved[] =
"c.pthread.rt.m.dl.util.xnet.";
const char *rp, *next;
for (rp=reserved; *rp; rp=next) {
next = strchr(rp, '.') + 1;
if (strncmp(name+3, rp, next-rp) == 0)
break;
}
if (*rp) {
if (ldd_mode) {
/* Track which names have been resolved
* and only report each one once. */
static unsigned reported;
unsigned mask = 1U<<(rp-reserved);
if (!(reported & mask)) {
reported |= mask;
dprintf(1, "\t%s => %s (%p)\n",
name, ldso.name,
ldso.base);
}
}
is_self = 1;
}
}
if (!strcmp(name, ldso.name)) is_self = 1;
if (is_self) {
if (!ldso.prev) {
tail->next = &ldso;
ldso.prev = tail;
rework ldso handling of global symbol table for consistency when loading libraries with dlopen, the caller can request that the library's symbols become part of the global symbol table, or that they only be used for resolving relocations in the loaded library and its dependencies. in the latter case, a subsequent dlopen of the same library can upgrade it to global status. previously, if a library was upgraded from local to global mode, its symbols entered the symbol lookup search order at the point where the library was originally loaded. this means that a new call to dlopen could change the value of a symbol that already had a visible definition, an inconsistency which applications could observe. POSIX is unclear whether this should happen or whether it's permitted to happen, but the resolution of Austin Group issue #982 made it formally unspecified. with this patch, a library whose mode is upgraded from local to global enters the symbol lookup order at the point where it was made global, so that symbol resolution before and after the upgrade are consistent. in order to implement this change, the per-dso global flag is replaced with a separate set of linked-list pointers for participation in the global symbol table. this permits the order of dso objects for symbol resolution to differ from the order used for iteration of all loaded libraries. it also improves performance of find_sym, by avoiding a branch per iteration and skipping, and especially in the case where many non-global libraries have been loaded, by allowing the loop to skip over them entirely. logic for temporarily adding non-global libraries to the symbol table for relocation purposes is also mildly simplified.
2017-03-13 01:03:05 +00:00
tail = &ldso;
}
return &ldso;
}
if (strchr(name, '/')) {
pathname = name;
fd = open(name, O_RDONLY|O_CLOEXEC);
} else {
/* Search for the name to see if it's already loaded */
for (p=head->next; p; p=p->next) {
if (p->shortname && !strcmp(p->shortname, name)) {
return p;
}
}
if (strlen(name) > NAME_MAX) return 0;
fd = -1;
if (env_path) fd = path_open(name, env_path, buf, sizeof buf);
for (p=needed_by; fd == -1 && p; p=p->needed_by) {
if (fixup_rpath(p, buf, sizeof buf) < 0)
fd = -2; /* Inhibit further search. */
if (p->rpath)
fd = path_open(name, p->rpath, buf, sizeof buf);
}
if (fd == -1) {
if (!sys_path) {
char *prefix = 0;
size_t prefix_len;
if (ldso.name[0]=='/') {
char *s, *t, *z;
for (s=t=z=ldso.name; *s; s++)
if (*s=='/') z=t, t=s;
prefix_len = z-ldso.name;
if (prefix_len < PATH_MAX)
prefix = ldso.name;
}
if (!prefix) {
prefix = "";
prefix_len = 0;
}
char etc_ldso_path[prefix_len + 1
+ sizeof "/etc/ld-musl-" LDSO_ARCH ".path"];
snprintf(etc_ldso_path, sizeof etc_ldso_path,
"%.*s/etc/ld-musl-" LDSO_ARCH ".path",
(int)prefix_len, prefix);
FILE *f = fopen(etc_ldso_path, "rbe");
if (f) {
if (getdelim(&sys_path, (size_t[1]){0}, 0, f) <= 0) {
free(sys_path);
sys_path = "";
}
fclose(f);
} else if (errno != ENOENT) {
sys_path = "";
}
}
if (!sys_path) sys_path = "/lib:/usr/local/lib:/usr/lib";
fd = path_open(name, sys_path, buf, sizeof buf);
}
pathname = buf;
}
if (fd < 0) return 0;
if (fstat(fd, &st) < 0) {
close(fd);
return 0;
}
for (p=head->next; p; p=p->next) {
if (p->dev == st.st_dev && p->ino == st.st_ino) {
/* If this library was previously loaded with a
* pathname but a search found the same inode,
* setup its shortname so it can be found by name. */
if (!p->shortname && pathname != name)
p->shortname = strrchr(p->name, '/')+1;
close(fd);
return p;
}
}
map = noload ? 0 : map_library(fd, &temp_dso);
close(fd);
if (!map) return 0;
/* Avoid the danger of getting two versions of libc mapped into the
* same process when an absolute pathname was used. The symbols
* checked are chosen to catch both musl and glibc, and to avoid
* false positives from interposition-hack libraries. */
decode_dyn(&temp_dso);
if (find_sym(&temp_dso, "__libc_start_main", 1).sym &&
find_sym(&temp_dso, "stdin", 1).sym) {
unmap_library(&temp_dso);
return load_library("libc.so", needed_by);
}
/* Past this point, if we haven't reached runtime yet, ldso has
* committed either to use the mapped library or to abort execution.
* Unmapping is not possible, so we can safely reclaim gaps. */
if (!runtime) reclaim_gaps(&temp_dso);
/* Allocate storage for the new DSO. When there is TLS, this
* storage must include a reservation for all pre-existing
* threads to obtain copies of both the new TLS, and an
* extended DTV capable of storing an additional slot for
* the newly-loaded DSO. */
alloc_size = sizeof *p + strlen(pathname) + 1;
if (runtime && temp_dso.tls.image) {
size_t per_th = temp_dso.tls.size + temp_dso.tls.align
+ sizeof(void *) * (tls_cnt+3);
n_th = libc.threads_minus_1 + 1;
if (n_th > SSIZE_MAX / per_th) alloc_size = SIZE_MAX;
else alloc_size += n_th * per_th;
}
p = calloc(1, alloc_size);
if (!p) {
unmap_library(&temp_dso);
return 0;
}
memcpy(p, &temp_dso, sizeof temp_dso);
p->dev = st.st_dev;
p->ino = st.st_ino;
p->needed_by = needed_by;
p->name = p->buf;
strcpy(p->name, pathname);
/* Add a shortname only if name arg was not an explicit pathname. */
if (pathname != name) p->shortname = strrchr(p->name, '/')+1;
if (p->tls.image) {
p->tls_id = ++tls_cnt;
tls_align = MAXP2(tls_align, p->tls.align);
#ifdef TLS_ABOVE_TP
p->tls.offset = tls_offset + ( (tls_align-1) &
-(tls_offset + (uintptr_t)p->tls.image) );
tls_offset += p->tls.size;
#else
tls_offset += p->tls.size + p->tls.align - 1;
tls_offset -= (tls_offset + (uintptr_t)p->tls.image)
& (p->tls.align-1);
p->tls.offset = tls_offset;
#endif
p->new_dtv = (void *)(-sizeof(size_t) &
(uintptr_t)(p->name+strlen(p->name)+sizeof(size_t)));
p->new_tls = (void *)(p->new_dtv + n_th*(tls_cnt+1));
if (tls_tail) tls_tail->next = &p->tls;
else libc.tls_head = &p->tls;
tls_tail = &p->tls;
}
tail->next = p;
p->prev = tail;
tail = p;
if (DL_FDPIC) makefuncdescs(p);
if (ldd_mode) dprintf(1, "\t%s => %s (%p)\n", name, pathname, p->base);
return p;
}
static void load_deps(struct dso *p)
{
size_t i, ndeps=0;
struct dso ***deps = &p->deps, **tmp, *dep;
for (; p; p=p->next) {
for (i=0; p->dynv[i]; i+=2) {
if (p->dynv[i] != DT_NEEDED) continue;
dep = load_library(p->strings + p->dynv[i+1], p);
if (!dep) {
error("Error loading shared library %s: %m (needed by %s)",
p->strings + p->dynv[i+1], p->name);
if (runtime) longjmp(*rtld_fail, 1);
continue;
}
if (runtime) {
tmp = realloc(*deps, sizeof(*tmp)*(ndeps+2));
if (!tmp) longjmp(*rtld_fail, 1);
tmp[ndeps++] = dep;
tmp[ndeps] = 0;
*deps = tmp;
}
}
}
if (!*deps) *deps = (struct dso **)&nodeps_dummy;
}
2011-08-16 04:24:36 +00:00
static void load_preload(char *s)
{
int tmp;
char *z;
for (z=s; *z; s=z) {
for ( ; *s && (isspace(*s) || *s==':'); s++);
for (z=s; *z && !isspace(*z) && *z!=':'; z++);
2011-08-16 04:24:36 +00:00
tmp = *z;
*z = 0;
load_library(s, 0);
2011-08-16 04:24:36 +00:00
*z = tmp;
}
}
rework ldso handling of global symbol table for consistency when loading libraries with dlopen, the caller can request that the library's symbols become part of the global symbol table, or that they only be used for resolving relocations in the loaded library and its dependencies. in the latter case, a subsequent dlopen of the same library can upgrade it to global status. previously, if a library was upgraded from local to global mode, its symbols entered the symbol lookup search order at the point where the library was originally loaded. this means that a new call to dlopen could change the value of a symbol that already had a visible definition, an inconsistency which applications could observe. POSIX is unclear whether this should happen or whether it's permitted to happen, but the resolution of Austin Group issue #982 made it formally unspecified. with this patch, a library whose mode is upgraded from local to global enters the symbol lookup order at the point where it was made global, so that symbol resolution before and after the upgrade are consistent. in order to implement this change, the per-dso global flag is replaced with a separate set of linked-list pointers for participation in the global symbol table. this permits the order of dso objects for symbol resolution to differ from the order used for iteration of all loaded libraries. it also improves performance of find_sym, by avoiding a branch per iteration and skipping, and especially in the case where many non-global libraries have been loaded, by allowing the loop to skip over them entirely. logic for temporarily adding non-global libraries to the symbol table for relocation purposes is also mildly simplified.
2017-03-13 01:03:05 +00:00
static void add_syms(struct dso *p)
{
rework ldso handling of global symbol table for consistency when loading libraries with dlopen, the caller can request that the library's symbols become part of the global symbol table, or that they only be used for resolving relocations in the loaded library and its dependencies. in the latter case, a subsequent dlopen of the same library can upgrade it to global status. previously, if a library was upgraded from local to global mode, its symbols entered the symbol lookup search order at the point where the library was originally loaded. this means that a new call to dlopen could change the value of a symbol that already had a visible definition, an inconsistency which applications could observe. POSIX is unclear whether this should happen or whether it's permitted to happen, but the resolution of Austin Group issue #982 made it formally unspecified. with this patch, a library whose mode is upgraded from local to global enters the symbol lookup order at the point where it was made global, so that symbol resolution before and after the upgrade are consistent. in order to implement this change, the per-dso global flag is replaced with a separate set of linked-list pointers for participation in the global symbol table. this permits the order of dso objects for symbol resolution to differ from the order used for iteration of all loaded libraries. it also improves performance of find_sym, by avoiding a branch per iteration and skipping, and especially in the case where many non-global libraries have been loaded, by allowing the loop to skip over them entirely. logic for temporarily adding non-global libraries to the symbol table for relocation purposes is also mildly simplified.
2017-03-13 01:03:05 +00:00
if (!p->syms_next && syms_tail != p) {
syms_tail->syms_next = p;
syms_tail = p;
}
}
static void revert_syms(struct dso *old_tail)
{
struct dso *p, *next;
/* Chop off the tail of the list of dsos that participate in
* the global symbol table, reverting them to RTLD_LOCAL. */
for (p=old_tail; p; p=next) {
next = p->syms_next;
p->syms_next = 0;
}
syms_tail = old_tail;
}
static void do_mips_relocs(struct dso *p, size_t *got)
{
size_t i, j, rel[2];
unsigned char *base = p->base;
i=0; search_vec(p->dynv, &i, DT_MIPS_LOCAL_GOTNO);
reprocess all libc/ldso symbolic relocations in dynamic linking stage 3 commit f3ddd173806fd5c60b3f034528ca24542aecc5b9 introduced early relocations and subsequent reprocessing as part of the dynamic linker bootstrap overhaul, to allow use of arbitrary libc functions before the main application and libraries are loaded, but only reprocessed GOT/PLT relocation types. commit c093e2e8201524db0d638920e76bcb6b1d925f3a added reprocessing of non-GOT/PLT relocations to fix an actual regression that was observed on powerpc, but only for RELA format tables with out-of-line addends. REL table (inline addends at the relocation address) reprocessing is trickier because the first relocation pass clobbers the addends. this patch extends symbolic relocation reprocessing for libc/ldso to support all relocation types, whether REL or RELA format tables are used. it is believed not to alter behavior on any existing archs for the current dynamic linker and libc code. the motivations for this change are consistency and future-proofing. it ensures that behavior does not differ depending on whether REL or RELA tables are used, which could lead to undetected arch-specific bugs. it also ensures that, if in the future code depending on additional relocation types is added to libc.so, either at the source level or as part of the compiler runtime that gets pulled in (for example, soft-float with TLS for fenv), the new code will work properly. the implementation concept is simple: stage 2 of the dynamic linker counts the number of symbolic relocations in the libc/ldso REL table and allocates a VLA to save their addends into; stage 3 then uses the saved addends in place of the inline ones which were clobbered. for stack safety, a hard limit (currently 4k) is imposed on the number of such addends; this should be a couple orders of magnitude larger than the actual need. this number is not a runtime variable that could break fail-safety; it is constant for a given libc.so build.
2015-05-26 03:33:59 +00:00
if (p==&ldso) {
got += i;
} else {
while (i--) *got++ += (size_t)base;
}
j=0; search_vec(p->dynv, &j, DT_MIPS_GOTSYM);
i=0; search_vec(p->dynv, &i, DT_MIPS_SYMTABNO);
Sym *sym = p->syms + j;
rel[0] = (unsigned char *)got - base;
for (i-=j; i; i--, sym++, rel[0]+=sizeof(size_t)) {
rel[1] = R_INFO(sym-p->syms, R_MIPS_JUMP_SLOT);
do_relocs(p, rel, sizeof rel, 2);
}
}
static void reloc_all(struct dso *p)
{
size_t dyn[DYN_CNT];
for (; p; p=p->next) {
if (p->relocated) continue;
decode_vec(p->dynv, dyn, DYN_CNT);
if (NEED_MIPS_GOT_RELOCS)
do_mips_relocs(p, laddr(p, dyn[DT_PLTGOT]));
do_relocs(p, laddr(p, dyn[DT_JMPREL]), dyn[DT_PLTRELSZ],
2+(dyn[DT_PLTREL]==DT_RELA));
do_relocs(p, laddr(p, dyn[DT_REL]), dyn[DT_RELSZ], 2);
do_relocs(p, laddr(p, dyn[DT_RELA]), dyn[DT_RELASZ], 3);
2014-03-25 12:13:27 +00:00
if (head != &ldso && p->relro_start != p->relro_end &&
mprotect(laddr(p, p->relro_start), p->relro_end-p->relro_start, PROT_READ)
&& errno != ENOSYS) {
error("Error relocating %s: RELRO protection failed: %m",
2014-03-25 12:13:27 +00:00
p->name);
if (runtime) longjmp(*rtld_fail, 1);
2014-03-25 12:13:27 +00:00
}
p->relocated = 1;
}
}
static void kernel_mapped_dso(struct dso *p)
{
size_t min_addr = -1, max_addr = 0, cnt;
Phdr *ph = p->phdr;
for (cnt = p->phnum; cnt--; ph = (void *)((char *)ph + p->phentsize)) {
if (ph->p_type == PT_DYNAMIC) {
p->dynv = laddr(p, ph->p_vaddr);
} else if (ph->p_type == PT_GNU_RELRO) {
2014-03-25 12:13:27 +00:00
p->relro_start = ph->p_vaddr & -PAGE_SIZE;
p->relro_end = (ph->p_vaddr + ph->p_memsz) & -PAGE_SIZE;
} else if (ph->p_type == PT_GNU_STACK) {
if (!runtime && ph->p_memsz > __default_stacksize) {
__default_stacksize =
ph->p_memsz < DEFAULT_STACK_MAX ?
ph->p_memsz : DEFAULT_STACK_MAX;
}
2014-03-25 12:13:27 +00:00
}
if (ph->p_type != PT_LOAD) continue;
if (ph->p_vaddr < min_addr)
min_addr = ph->p_vaddr;
if (ph->p_vaddr+ph->p_memsz > max_addr)
max_addr = ph->p_vaddr+ph->p_memsz;
}
min_addr &= -PAGE_SIZE;
max_addr = (max_addr + PAGE_SIZE-1) & -PAGE_SIZE;
p->map = p->base + min_addr;
p->map_len = max_addr - min_addr;
p->kernel_mapped = 1;
}
void __libc_exit_fini()
{
struct dso *p;
size_t dyn[DYN_CNT];
for (p=fini_head; p; p=p->fini_next) {
if (!p->constructed) continue;
decode_vec(p->dynv, dyn, DYN_CNT);
if (dyn[0] & (1<<DT_FINI_ARRAY)) {
size_t n = dyn[DT_FINI_ARRAYSZ]/sizeof(size_t);
size_t *fn = (size_t *)laddr(p, dyn[DT_FINI_ARRAY])+n;
while (n--) ((void (*)(void))*--fn)();
}
#ifndef NO_LEGACY_INITFINI
if ((dyn[0] & (1<<DT_FINI)) && dyn[DT_FINI])
fpaddr(p, dyn[DT_FINI])();
#endif
}
}
static void do_init_fini(struct dso *p)
{
size_t dyn[DYN_CNT];
int need_locking = libc.threads_minus_1;
/* Allow recursive calls that arise when a library calls
* dlopen from one of its constructors, but block any
* other threads until all ctors have finished. */
if (need_locking) pthread_mutex_lock(&init_fini_lock);
for (; p; p=p->prev) {
if (p->constructed) continue;
p->constructed = 1;
decode_vec(p->dynv, dyn, DYN_CNT);
if (dyn[0] & ((1<<DT_FINI) | (1<<DT_FINI_ARRAY))) {
p->fini_next = fini_head;
fini_head = p;
}
#ifndef NO_LEGACY_INITFINI
if ((dyn[0] & (1<<DT_INIT)) && dyn[DT_INIT])
fpaddr(p, dyn[DT_INIT])();
#endif
if (dyn[0] & (1<<DT_INIT_ARRAY)) {
size_t n = dyn[DT_INIT_ARRAYSZ]/sizeof(size_t);
size_t *fn = laddr(p, dyn[DT_INIT_ARRAY]);
while (n--) ((void (*)(void))*fn++)();
}
if (!need_locking && libc.threads_minus_1) {
need_locking = 1;
pthread_mutex_lock(&init_fini_lock);
}
}
if (need_locking) pthread_mutex_unlock(&init_fini_lock);
}
void __libc_start_init(void)
{
do_init_fini(tail);
}
static void dl_debug_state(void)
{
}
weak_alias(dl_debug_state, _dl_debug_state);
void __init_tls(size_t *auxv)
{
}
hidden void *__tls_get_new(tls_mod_off_t *v)
{
pthread_t self = __pthread_self();
/* Block signals to make accessing new TLS async-signal-safe */
sigset_t set;
__block_all_sigs(&set);
if (v[0] <= self->dtv[0]) {
__restore_sigs(&set);
return (void *)(self->dtv[v[0]] + v[1]);
}
/* This is safe without any locks held because, if the caller
* is able to request the Nth entry of the DTV, the DSO list
* must be valid at least that far out and it was synchronized
* at program startup or by an already-completed call to dlopen. */
struct dso *p;
for (p=head; p->tls_id != v[0]; p=p->next);
/* Get new DTV space from new DSO */
uintptr_t *newdtv = p->new_dtv +
(v[0]+1)*a_fetch_add(&p->new_dtv_idx,1);
memcpy(newdtv, self->dtv, (self->dtv[0]+1) * sizeof(uintptr_t));
newdtv[0] = v[0];
self->dtv = self->dtv_copy = newdtv;
/* Get new TLS memory from all new DSOs up to the requested one */
unsigned char *mem;
for (p=head; ; p=p->next) {
if (!p->tls_id || self->dtv[p->tls_id]) continue;
mem = p->new_tls + (p->tls.size + p->tls.align)
* a_fetch_add(&p->new_tls_idx,1);
mem += ((uintptr_t)p->tls.image - (uintptr_t)mem)
& (p->tls.align-1);
self->dtv[p->tls_id] = (uintptr_t)mem + DTP_OFFSET;
memcpy(mem, p->tls.image, p->tls.len);
if (p->tls_id == v[0]) break;
}
__restore_sigs(&set);
return mem + v[1] + DTP_OFFSET;
}
static void update_tls_size()
{
libc.tls_cnt = tls_cnt;
libc.tls_align = tls_align;
libc.tls_size = ALIGN(
(1+tls_cnt) * sizeof(void *) +
tls_offset +
sizeof(struct pthread) +
tls_align * 2,
tls_align);
}
/* Stage 1 of the dynamic linker is defined in dlstart.c. It calls the
* following stage 2 and stage 3 functions via primitive symbolic lookup
* since it does not have access to their addresses to begin with. */
/* Stage 2 of the dynamic linker is called after relative relocations
* have been processed. It can make function calls to static functions
* and access string literals and static data, but cannot use extern
* symbols. Its job is to perform symbolic relocations on the dynamic
* linker itself, but some of the relocations performed may need to be
* replaced later due to copy relocations in the main program. */
hidden void __dls2(unsigned char *base, size_t *sp)
{
if (DL_FDPIC) {
void *p1 = (void *)sp[-2];
void *p2 = (void *)sp[-1];
if (!p1) {
size_t *auxv, aux[AUX_CNT];
for (auxv=sp+1+*sp+1; *auxv; auxv++);
auxv++;
decode_vec(auxv, aux, AUX_CNT);
if (aux[AT_BASE]) ldso.base = (void *)aux[AT_BASE];
else ldso.base = (void *)(aux[AT_PHDR] & -4096);
}
app_loadmap = p2 ? p1 : 0;
ldso.loadmap = p2 ? p2 : p1;
ldso.base = laddr(&ldso, 0);
} else {
ldso.base = base;
}
Ehdr *ehdr = (void *)ldso.base;
ldso.name = ldso.shortname = "libc.so";
ldso.phnum = ehdr->e_phnum;
ldso.phdr = laddr(&ldso, ehdr->e_phoff);
ldso.phentsize = ehdr->e_phentsize;
kernel_mapped_dso(&ldso);
decode_dyn(&ldso);
if (DL_FDPIC) makefuncdescs(&ldso);
reprocess all libc/ldso symbolic relocations in dynamic linking stage 3 commit f3ddd173806fd5c60b3f034528ca24542aecc5b9 introduced early relocations and subsequent reprocessing as part of the dynamic linker bootstrap overhaul, to allow use of arbitrary libc functions before the main application and libraries are loaded, but only reprocessed GOT/PLT relocation types. commit c093e2e8201524db0d638920e76bcb6b1d925f3a added reprocessing of non-GOT/PLT relocations to fix an actual regression that was observed on powerpc, but only for RELA format tables with out-of-line addends. REL table (inline addends at the relocation address) reprocessing is trickier because the first relocation pass clobbers the addends. this patch extends symbolic relocation reprocessing for libc/ldso to support all relocation types, whether REL or RELA format tables are used. it is believed not to alter behavior on any existing archs for the current dynamic linker and libc code. the motivations for this change are consistency and future-proofing. it ensures that behavior does not differ depending on whether REL or RELA tables are used, which could lead to undetected arch-specific bugs. it also ensures that, if in the future code depending on additional relocation types is added to libc.so, either at the source level or as part of the compiler runtime that gets pulled in (for example, soft-float with TLS for fenv), the new code will work properly. the implementation concept is simple: stage 2 of the dynamic linker counts the number of symbolic relocations in the libc/ldso REL table and allocates a VLA to save their addends into; stage 3 then uses the saved addends in place of the inline ones which were clobbered. for stack safety, a hard limit (currently 4k) is imposed on the number of such addends; this should be a couple orders of magnitude larger than the actual need. this number is not a runtime variable that could break fail-safety; it is constant for a given libc.so build.
2015-05-26 03:33:59 +00:00
/* Prepare storage for to save clobbered REL addends so they
* can be reused in stage 3. There should be very few. If
* something goes wrong and there are a huge number, abort
* instead of risking stack overflow. */
size_t dyn[DYN_CNT];
decode_vec(ldso.dynv, dyn, DYN_CNT);
size_t *rel = laddr(&ldso, dyn[DT_REL]);
reprocess all libc/ldso symbolic relocations in dynamic linking stage 3 commit f3ddd173806fd5c60b3f034528ca24542aecc5b9 introduced early relocations and subsequent reprocessing as part of the dynamic linker bootstrap overhaul, to allow use of arbitrary libc functions before the main application and libraries are loaded, but only reprocessed GOT/PLT relocation types. commit c093e2e8201524db0d638920e76bcb6b1d925f3a added reprocessing of non-GOT/PLT relocations to fix an actual regression that was observed on powerpc, but only for RELA format tables with out-of-line addends. REL table (inline addends at the relocation address) reprocessing is trickier because the first relocation pass clobbers the addends. this patch extends symbolic relocation reprocessing for libc/ldso to support all relocation types, whether REL or RELA format tables are used. it is believed not to alter behavior on any existing archs for the current dynamic linker and libc code. the motivations for this change are consistency and future-proofing. it ensures that behavior does not differ depending on whether REL or RELA tables are used, which could lead to undetected arch-specific bugs. it also ensures that, if in the future code depending on additional relocation types is added to libc.so, either at the source level or as part of the compiler runtime that gets pulled in (for example, soft-float with TLS for fenv), the new code will work properly. the implementation concept is simple: stage 2 of the dynamic linker counts the number of symbolic relocations in the libc/ldso REL table and allocates a VLA to save their addends into; stage 3 then uses the saved addends in place of the inline ones which were clobbered. for stack safety, a hard limit (currently 4k) is imposed on the number of such addends; this should be a couple orders of magnitude larger than the actual need. this number is not a runtime variable that could break fail-safety; it is constant for a given libc.so build.
2015-05-26 03:33:59 +00:00
size_t rel_size = dyn[DT_RELSZ];
size_t symbolic_rel_cnt = 0;
apply_addends_to = rel;
for (; rel_size; rel+=2, rel_size-=2*sizeof(size_t))
if (!IS_RELATIVE(rel[1], ldso.syms)) symbolic_rel_cnt++;
reprocess all libc/ldso symbolic relocations in dynamic linking stage 3 commit f3ddd173806fd5c60b3f034528ca24542aecc5b9 introduced early relocations and subsequent reprocessing as part of the dynamic linker bootstrap overhaul, to allow use of arbitrary libc functions before the main application and libraries are loaded, but only reprocessed GOT/PLT relocation types. commit c093e2e8201524db0d638920e76bcb6b1d925f3a added reprocessing of non-GOT/PLT relocations to fix an actual regression that was observed on powerpc, but only for RELA format tables with out-of-line addends. REL table (inline addends at the relocation address) reprocessing is trickier because the first relocation pass clobbers the addends. this patch extends symbolic relocation reprocessing for libc/ldso to support all relocation types, whether REL or RELA format tables are used. it is believed not to alter behavior on any existing archs for the current dynamic linker and libc code. the motivations for this change are consistency and future-proofing. it ensures that behavior does not differ depending on whether REL or RELA tables are used, which could lead to undetected arch-specific bugs. it also ensures that, if in the future code depending on additional relocation types is added to libc.so, either at the source level or as part of the compiler runtime that gets pulled in (for example, soft-float with TLS for fenv), the new code will work properly. the implementation concept is simple: stage 2 of the dynamic linker counts the number of symbolic relocations in the libc/ldso REL table and allocates a VLA to save their addends into; stage 3 then uses the saved addends in place of the inline ones which were clobbered. for stack safety, a hard limit (currently 4k) is imposed on the number of such addends; this should be a couple orders of magnitude larger than the actual need. this number is not a runtime variable that could break fail-safety; it is constant for a given libc.so build.
2015-05-26 03:33:59 +00:00
if (symbolic_rel_cnt >= ADDEND_LIMIT) a_crash();
size_t addends[symbolic_rel_cnt+1];
saved_addends = addends;
head = &ldso;
reloc_all(&ldso);
ldso.relocated = 0;
/* Call dynamic linker stage-2b, __dls2b, looking it up
* symbolically as a barrier against moving the address
* load across the above relocation processing. */
struct symdef dls2b_def = find_sym(&ldso, "__dls2b", 0);
if (DL_FDPIC) ((stage3_func)&ldso.funcdescs[dls2b_def.sym-ldso.syms])(sp);
else ((stage3_func)laddr(&ldso, dls2b_def.sym->st_value))(sp);
}
/* Stage 2b sets up a valid thread pointer, which requires relocations
* completed in stage 2, and on which stage 3 is permitted to depend.
* This is done as a separate stage, with symbolic lookup as a barrier,
* so that loads of the thread pointer and &errno can be pure/const and
* thereby hoistable. */
_Noreturn void __dls2b(size_t *sp)
{
/* Setup early thread pointer in builtin_tls for ldso/libc itself to
* use during dynamic linking. If possible it will also serve as the
* thread pointer at runtime. */
libc.tls_size = sizeof builtin_tls;
libc.tls_align = tls_align;
if (__init_tp(__copy_tls((void *)builtin_tls)) < 0) {
a_crash();
}
struct symdef dls3_def = find_sym(&ldso, "__dls3", 0);
if (DL_FDPIC) ((stage3_func)&ldso.funcdescs[dls3_def.sym-ldso.syms])(sp);
else ((stage3_func)laddr(&ldso, dls3_def.sym->st_value))(sp);
}
/* Stage 3 of the dynamic linker is called with the dynamic linker/libc
* fully functional. Its job is to load (if not already loaded) and
* process dependencies and relocations for the main application and
* transfer control to its entry point. */
_Noreturn void __dls3(size_t *sp)
{
static struct dso app, vdso;
size_t aux[AUX_CNT], *auxv;
size_t i;
2011-08-16 04:24:36 +00:00
char *env_preload=0;
char *replace_argv0=0;
2012-08-25 21:31:59 +00:00
size_t vdso_base;
int argc = *sp;
char **argv = (void *)(sp+1);
char **argv_orig = argv;
add support for init/fini array in main program, and greatly simplify modern (4.7.x and later) gcc uses init/fini arrays, rather than the legacy _init/_fini function pasting and crtbegin/crtend ctors/dtors system, on most or all archs. some archs had already switched a long time ago. without following this change, global ctors/dtors will cease to work under musl when building with new gcc versions. the most surprising part of this patch is that it actually reduces the size of the init code, for both static and shared libc. this is achieved by (1) unifying the handling main program and shared libraries in the dynamic linker, and (2) eliminating the glibc-inspired rube goldberg machine for passing around init and fini function pointers. to clarify, some background: the function signature for __libc_start_main was based on glibc, as part of the original goal of being able to run some glibc-linked binaries. it worked by having the crt1 code, which is linked into every application, static or dynamic, obtain and pass pointers to the init and fini functions, which __libc_start_main is then responsible for using and recording for later use, as necessary. however, in neither the static-linked nor dynamic-linked case do we actually need crt1.o's help. with dynamic linking, all the pointers are available in the _DYNAMIC block. with static linking, it's safe to simply access the _init/_fini and __init_array_start, etc. symbols directly. obviously changing the __libc_start_main function signature in an incompatible way would break both old musl-linked programs and glibc-linked programs, so let's not do that. instead, the function can just ignore the information it doesn't need. new archs need not even provide the useless args in their versions of crt1.o. existing archs should continue to provide it as long as there is an interest in having newly-linked applications be able to run on old versions of musl; at some point in the future, this support can be removed.
2013-07-21 07:00:54 +00:00
char **envp = argv+argc+1;
/* Find aux vector just past environ[] and use it to initialize
* global data that may be needed before we can make syscalls. */
__environ = envp;
for (i=argc+1; argv[i]; i++);
libc.auxv = auxv = (void *)(argv+i+1);
decode_vec(auxv, aux, AUX_CNT);
__hwcap = aux[AT_HWCAP];
libc.page_size = aux[AT_PAGESZ];
libc.secure = ((aux[0]&0x7800)!=0x7800 || aux[AT_UID]!=aux[AT_EUID]
|| aux[AT_GID]!=aux[AT_EGID] || aux[AT_SECURE]);
/* Only trust user/env if kernel says we're not suid/sgid */
if (!libc.secure) {
env_path = getenv("LD_LIBRARY_PATH");
env_preload = getenv("LD_PRELOAD");
}
/* If the main program was already loaded by the kernel,
* AT_PHDR will point to some location other than the dynamic
* linker's program headers. */
if (aux[AT_PHDR] != (size_t)ldso.phdr) {
size_t interp_off = 0;
size_t tls_image = 0;
/* Find load address of the main program, via AT_PHDR vs PT_PHDR. */
Phdr *phdr = app.phdr = (void *)aux[AT_PHDR];
app.phnum = aux[AT_PHNUM];
app.phentsize = aux[AT_PHENT];
for (i=aux[AT_PHNUM]; i; i--, phdr=(void *)((char *)phdr + aux[AT_PHENT])) {
if (phdr->p_type == PT_PHDR)
app.base = (void *)(aux[AT_PHDR] - phdr->p_vaddr);
else if (phdr->p_type == PT_INTERP)
interp_off = (size_t)phdr->p_vaddr;
else if (phdr->p_type == PT_TLS) {
tls_image = phdr->p_vaddr;
app.tls.len = phdr->p_filesz;
app.tls.size = phdr->p_memsz;
app.tls.align = phdr->p_align;
}
}
if (DL_FDPIC) app.loadmap = app_loadmap;
if (app.tls.size) app.tls.image = laddr(&app, tls_image);
if (interp_off) ldso.name = laddr(&app, interp_off);
if ((aux[0] & (1UL<<AT_EXECFN))
&& strncmp((char *)aux[AT_EXECFN], "/proc/", 6))
app.name = (char *)aux[AT_EXECFN];
else
app.name = argv[0];
kernel_mapped_dso(&app);
} else {
int fd;
char *ldname = argv[0];
size_t l = strlen(ldname);
if (l >= 3 && !strcmp(ldname+l-3, "ldd")) ldd_mode = 1;
argv++;
while (argv[0] && argv[0][0]=='-' && argv[0][1]=='-') {
char *opt = argv[0]+2;
*argv++ = (void *)-1;
if (!*opt) {
break;
} else if (!memcmp(opt, "list", 5)) {
ldd_mode = 1;
} else if (!memcmp(opt, "library-path", 12)) {
if (opt[12]=='=') env_path = opt+13;
else if (opt[12]) *argv = 0;
else if (*argv) env_path = *argv++;
} else if (!memcmp(opt, "preload", 7)) {
if (opt[7]=='=') env_preload = opt+8;
else if (opt[7]) *argv = 0;
else if (*argv) env_preload = *argv++;
} else if (!memcmp(opt, "argv0", 5)) {
if (opt[5]=='=') replace_argv0 = opt+6;
else if (opt[5]) *argv = 0;
else if (*argv) replace_argv0 = *argv++;
} else {
argv[0] = 0;
}
}
argv[-1] = (void *)(argc - (argv-argv_orig));
if (!argv[0]) {
dprintf(2, "musl libc (" LDSO_ARCH ")\n"
"Version %s\n"
"Dynamic Program Loader\n"
"Usage: %s [options] [--] pathname%s\n",
__libc_version, ldname,
ldd_mode ? "" : " [args]");
_exit(1);
}
fd = open(argv[0], O_RDONLY);
if (fd < 0) {
dprintf(2, "%s: cannot load %s: %s\n", ldname, argv[0], strerror(errno));
_exit(1);
}
Ehdr *ehdr = (void *)map_library(fd, &app);
if (!ehdr) {
dprintf(2, "%s: %s: Not a valid dynamic program\n", ldname, argv[0]);
_exit(1);
}
close(fd);
ldso.name = ldname;
app.name = argv[0];
aux[AT_ENTRY] = (size_t)laddr(&app, ehdr->e_entry);
/* Find the name that would have been used for the dynamic
* linker had ldd not taken its place. */
if (ldd_mode) {
for (i=0; i<app.phnum; i++) {
if (app.phdr[i].p_type == PT_INTERP)
ldso.name = laddr(&app, app.phdr[i].p_vaddr);
}
dprintf(1, "\t%s (%p)\n", ldso.name, ldso.base);
}
}
if (app.tls.size) {
libc.tls_head = tls_tail = &app.tls;
app.tls_id = tls_cnt = 1;
#ifdef TLS_ABOVE_TP
app.tls.offset = GAP_ABOVE_TP;
app.tls.offset += -GAP_ABOVE_TP & (app.tls.align-1);
tls_offset = app.tls.offset + app.tls.size
+ ( -((uintptr_t)app.tls.image + app.tls.size)
& (app.tls.align-1) );
#else
tls_offset = app.tls.offset = app.tls.size
+ ( -((uintptr_t)app.tls.image + app.tls.size)
& (app.tls.align-1) );
#endif
tls_align = MAXP2(tls_align, app.tls.align);
}
decode_dyn(&app);
if (DL_FDPIC) {
makefuncdescs(&app);
if (!app.loadmap) {
app.loadmap = (void *)&app_dummy_loadmap;
app.loadmap->nsegs = 1;
app.loadmap->segs[0].addr = (size_t)app.map;
app.loadmap->segs[0].p_vaddr = (size_t)app.map
- (size_t)app.base;
app.loadmap->segs[0].p_memsz = app.map_len;
}
argv[-3] = (void *)app.loadmap;
}
rework ldso handling of global symbol table for consistency when loading libraries with dlopen, the caller can request that the library's symbols become part of the global symbol table, or that they only be used for resolving relocations in the loaded library and its dependencies. in the latter case, a subsequent dlopen of the same library can upgrade it to global status. previously, if a library was upgraded from local to global mode, its symbols entered the symbol lookup search order at the point where the library was originally loaded. this means that a new call to dlopen could change the value of a symbol that already had a visible definition, an inconsistency which applications could observe. POSIX is unclear whether this should happen or whether it's permitted to happen, but the resolution of Austin Group issue #982 made it formally unspecified. with this patch, a library whose mode is upgraded from local to global enters the symbol lookup order at the point where it was made global, so that symbol resolution before and after the upgrade are consistent. in order to implement this change, the per-dso global flag is replaced with a separate set of linked-list pointers for participation in the global symbol table. this permits the order of dso objects for symbol resolution to differ from the order used for iteration of all loaded libraries. it also improves performance of find_sym, by avoiding a branch per iteration and skipping, and especially in the case where many non-global libraries have been loaded, by allowing the loop to skip over them entirely. logic for temporarily adding non-global libraries to the symbol table for relocation purposes is also mildly simplified.
2017-03-13 01:03:05 +00:00
/* Initial dso chain consists only of the app. */
head = tail = syms_tail = &app;
/* Donate unused parts of app and library mapping to malloc */
reclaim_gaps(&app);
reclaim_gaps(&ldso);
/* Load preload/needed libraries, add symbols to global namespace. */
if (env_preload) load_preload(env_preload);
load_deps(&app);
for (struct dso *p=head; p; p=p->next)
add_syms(p);
/* Attach to vdso, if provided by the kernel, last so that it does
* not become part of the global namespace. */
if (search_vec(auxv, &vdso_base, AT_SYSINFO_EHDR) && vdso_base) {
Ehdr *ehdr = (void *)vdso_base;
Phdr *phdr = vdso.phdr = (void *)(vdso_base + ehdr->e_phoff);
vdso.phnum = ehdr->e_phnum;
vdso.phentsize = ehdr->e_phentsize;
for (i=ehdr->e_phnum; i; i--, phdr=(void *)((char *)phdr + ehdr->e_phentsize)) {
if (phdr->p_type == PT_DYNAMIC)
vdso.dynv = (void *)(vdso_base + phdr->p_offset);
if (phdr->p_type == PT_LOAD)
vdso.base = (void *)(vdso_base - phdr->p_vaddr + phdr->p_offset);
}
vdso.name = "";
vdso.shortname = "linux-gate.so.1";
vdso.relocated = 1;
decode_dyn(&vdso);
rework ldso handling of global symbol table for consistency when loading libraries with dlopen, the caller can request that the library's symbols become part of the global symbol table, or that they only be used for resolving relocations in the loaded library and its dependencies. in the latter case, a subsequent dlopen of the same library can upgrade it to global status. previously, if a library was upgraded from local to global mode, its symbols entered the symbol lookup search order at the point where the library was originally loaded. this means that a new call to dlopen could change the value of a symbol that already had a visible definition, an inconsistency which applications could observe. POSIX is unclear whether this should happen or whether it's permitted to happen, but the resolution of Austin Group issue #982 made it formally unspecified. with this patch, a library whose mode is upgraded from local to global enters the symbol lookup order at the point where it was made global, so that symbol resolution before and after the upgrade are consistent. in order to implement this change, the per-dso global flag is replaced with a separate set of linked-list pointers for participation in the global symbol table. this permits the order of dso objects for symbol resolution to differ from the order used for iteration of all loaded libraries. it also improves performance of find_sym, by avoiding a branch per iteration and skipping, and especially in the case where many non-global libraries have been loaded, by allowing the loop to skip over them entirely. logic for temporarily adding non-global libraries to the symbol table for relocation purposes is also mildly simplified.
2017-03-13 01:03:05 +00:00
vdso.prev = tail;
tail->next = &vdso;
tail = &vdso;
}
for (i=0; app.dynv[i]; i+=2) {
if (!DT_DEBUG_INDIRECT && app.dynv[i]==DT_DEBUG)
app.dynv[i+1] = (size_t)&debug;
if (DT_DEBUG_INDIRECT && app.dynv[i]==DT_DEBUG_INDIRECT) {
size_t *ptr = (size_t *) app.dynv[i+1];
*ptr = (size_t)&debug;
}
}
2014-03-25 12:13:27 +00:00
/* The main program must be relocated LAST since it may contin
* copy relocations which depend on libraries' relocations. */
reloc_all(app.next);
reloc_all(&app);
update_tls_size();
if (libc.tls_size > sizeof builtin_tls || tls_align > MIN_TLS_ALIGN) {
void *initial_tls = calloc(libc.tls_size, 1);
always initialize thread pointer at program start this is the first step in an overhaul aimed at greatly simplifying and optimizing everything dealing with thread-local state. previously, the thread pointer was initialized lazily on first access, or at program startup if stack protector was in use, or at certain random places where inconsistent state could be reached if it were not initialized early. while believed to be fully correct, the logic was fragile and non-obvious. in the first phase of the thread pointer overhaul, support is retained (and in some cases improved) for systems/situation where loading the thread pointer fails, e.g. old kernels. some notes on specific changes: - the confusing use of libc.main_thread as an indicator that the thread pointer is initialized is eliminated in favor of an explicit has_thread_pointer predicate. - sigaction no longer needs to ensure that the thread pointer is initialized before installing a signal handler (this was needed to prevent a situation where the signal handler caused the thread pointer to be initialized and the subsequent sigreturn cleared it again) but it still needs to ensure that implementation-internal thread-related signals are not blocked. - pthread tsd initialization for the main thread is deferred in a new manner to minimize bloat in the static-linked __init_tp code. - pthread_setcancelstate no longer needs special handling for the situation before the thread pointer is initialized. it simply fails on systems that cannot support a thread pointer, which are non-conforming anyway. - pthread_cleanup_push/pop now check for missing thread pointer and nop themselves out in this case, so stdio no longer needs to avoid the cancellable path when the thread pointer is not available. a number of cases remain where certain interfaces may crash if the system does not support a thread pointer. at this point, these should be limited to pthread interfaces, and the number of such cases should be fewer than before.
2014-03-24 20:57:11 +00:00
if (!initial_tls) {
dprintf(2, "%s: Error getting %zu bytes thread-local storage: %m\n",
argv[0], libc.tls_size);
_exit(127);
}
if (__init_tp(__copy_tls(initial_tls)) < 0) {
a_crash();
}
always initialize thread pointer at program start this is the first step in an overhaul aimed at greatly simplifying and optimizing everything dealing with thread-local state. previously, the thread pointer was initialized lazily on first access, or at program startup if stack protector was in use, or at certain random places where inconsistent state could be reached if it were not initialized early. while believed to be fully correct, the logic was fragile and non-obvious. in the first phase of the thread pointer overhaul, support is retained (and in some cases improved) for systems/situation where loading the thread pointer fails, e.g. old kernels. some notes on specific changes: - the confusing use of libc.main_thread as an indicator that the thread pointer is initialized is eliminated in favor of an explicit has_thread_pointer predicate. - sigaction no longer needs to ensure that the thread pointer is initialized before installing a signal handler (this was needed to prevent a situation where the signal handler caused the thread pointer to be initialized and the subsequent sigreturn cleared it again) but it still needs to ensure that implementation-internal thread-related signals are not blocked. - pthread tsd initialization for the main thread is deferred in a new manner to minimize bloat in the static-linked __init_tp code. - pthread_setcancelstate no longer needs special handling for the situation before the thread pointer is initialized. it simply fails on systems that cannot support a thread pointer, which are non-conforming anyway. - pthread_cleanup_push/pop now check for missing thread pointer and nop themselves out in this case, so stdio no longer needs to avoid the cancellable path when the thread pointer is not available. a number of cases remain where certain interfaces may crash if the system does not support a thread pointer. at this point, these should be limited to pthread interfaces, and the number of such cases should be fewer than before.
2014-03-24 20:57:11 +00:00
} else {
size_t tmp_tls_size = libc.tls_size;
pthread_t self = __pthread_self();
/* Temporarily set the tls size to the full size of
* builtin_tls so that __copy_tls will use the same layout
* as it did for before. Then check, just to be safe. */
libc.tls_size = sizeof builtin_tls;
if (__copy_tls((void*)builtin_tls) != self) a_crash();
libc.tls_size = tmp_tls_size;
}
static_tls_cnt = tls_cnt;
if (ldso_fail) _exit(127);
if (ldd_mode) _exit(0);
/* Determine if malloc was interposed by a replacement implementation
* so that calloc and the memalign family can harden against the
* possibility of incomplete replacement. */
if (find_sym(head, "malloc", 1).dso != &ldso)
__malloc_replaced = 1;
/* Switch to runtime mode: any further failures in the dynamic
* linker are a reportable failure rather than a fatal startup
* error. */
runtime = 1;
debug.ver = 1;
debug.bp = dl_debug_state;
debug.head = head;
debug.base = ldso.base;
debug.state = 0;
_dl_debug_state();
if (replace_argv0) argv[0] = replace_argv0;
add support for init/fini array in main program, and greatly simplify modern (4.7.x and later) gcc uses init/fini arrays, rather than the legacy _init/_fini function pasting and crtbegin/crtend ctors/dtors system, on most or all archs. some archs had already switched a long time ago. without following this change, global ctors/dtors will cease to work under musl when building with new gcc versions. the most surprising part of this patch is that it actually reduces the size of the init code, for both static and shared libc. this is achieved by (1) unifying the handling main program and shared libraries in the dynamic linker, and (2) eliminating the glibc-inspired rube goldberg machine for passing around init and fini function pointers. to clarify, some background: the function signature for __libc_start_main was based on glibc, as part of the original goal of being able to run some glibc-linked binaries. it worked by having the crt1 code, which is linked into every application, static or dynamic, obtain and pass pointers to the init and fini functions, which __libc_start_main is then responsible for using and recording for later use, as necessary. however, in neither the static-linked nor dynamic-linked case do we actually need crt1.o's help. with dynamic linking, all the pointers are available in the _DYNAMIC block. with static linking, it's safe to simply access the _init/_fini and __init_array_start, etc. symbols directly. obviously changing the __libc_start_main function signature in an incompatible way would break both old musl-linked programs and glibc-linked programs, so let's not do that. instead, the function can just ignore the information it doesn't need. new archs need not even provide the useless args in their versions of crt1.o. existing archs should continue to provide it as long as there is an interest in having newly-linked applications be able to run on old versions of musl; at some point in the future, this support can be removed.
2013-07-21 07:00:54 +00:00
errno = 0;
CRTJMP((void *)aux[AT_ENTRY], argv-1);
for(;;);
}
static void prepare_lazy(struct dso *p)
{
size_t dyn[DYN_CNT], n, flags1=0;
decode_vec(p->dynv, dyn, DYN_CNT);
search_vec(p->dynv, &flags1, DT_FLAGS_1);
if (dyn[DT_BIND_NOW] || (dyn[DT_FLAGS] & DF_BIND_NOW) || (flags1 & DF_1_NOW))
return;
n = dyn[DT_RELSZ]/2 + dyn[DT_RELASZ]/3 + dyn[DT_PLTRELSZ]/2 + 1;
if (NEED_MIPS_GOT_RELOCS) {
size_t j=0; search_vec(p->dynv, &j, DT_MIPS_GOTSYM);
size_t i=0; search_vec(p->dynv, &i, DT_MIPS_SYMTABNO);
n += i-j;
}
p->lazy = calloc(n, 3*sizeof(size_t));
if (!p->lazy) {
error("Error preparing lazy relocation for %s: %m", p->name);
longjmp(*rtld_fail, 1);
}
p->lazy_next = lazy_head;
lazy_head = p;
}
void *dlopen(const char *file, int mode)
{
struct dso *volatile p, *orig_tail, *orig_syms_tail, *orig_lazy_head, *next;
struct tls_module *orig_tls_tail;
size_t orig_tls_cnt, orig_tls_offset, orig_tls_align;
size_t i;
int cs;
jmp_buf jb;
if (!file) return head;
pthread_setcancelstate(PTHREAD_CANCEL_DISABLE, &cs);
pthread_rwlock_wrlock(&lock);
__inhibit_ptc();
p = 0;
orig_tls_tail = tls_tail;
orig_tls_cnt = tls_cnt;
orig_tls_offset = tls_offset;
orig_tls_align = tls_align;
orig_lazy_head = lazy_head;
rework ldso handling of global symbol table for consistency when loading libraries with dlopen, the caller can request that the library's symbols become part of the global symbol table, or that they only be used for resolving relocations in the loaded library and its dependencies. in the latter case, a subsequent dlopen of the same library can upgrade it to global status. previously, if a library was upgraded from local to global mode, its symbols entered the symbol lookup search order at the point where the library was originally loaded. this means that a new call to dlopen could change the value of a symbol that already had a visible definition, an inconsistency which applications could observe. POSIX is unclear whether this should happen or whether it's permitted to happen, but the resolution of Austin Group issue #982 made it formally unspecified. with this patch, a library whose mode is upgraded from local to global enters the symbol lookup order at the point where it was made global, so that symbol resolution before and after the upgrade are consistent. in order to implement this change, the per-dso global flag is replaced with a separate set of linked-list pointers for participation in the global symbol table. this permits the order of dso objects for symbol resolution to differ from the order used for iteration of all loaded libraries. it also improves performance of find_sym, by avoiding a branch per iteration and skipping, and especially in the case where many non-global libraries have been loaded, by allowing the loop to skip over them entirely. logic for temporarily adding non-global libraries to the symbol table for relocation purposes is also mildly simplified.
2017-03-13 01:03:05 +00:00
orig_syms_tail = syms_tail;
orig_tail = tail;
noload = mode & RTLD_NOLOAD;
rtld_fail = &jb;
if (setjmp(*rtld_fail)) {
/* Clean up anything new that was (partially) loaded */
rework ldso handling of global symbol table for consistency when loading libraries with dlopen, the caller can request that the library's symbols become part of the global symbol table, or that they only be used for resolving relocations in the loaded library and its dependencies. in the latter case, a subsequent dlopen of the same library can upgrade it to global status. previously, if a library was upgraded from local to global mode, its symbols entered the symbol lookup search order at the point where the library was originally loaded. this means that a new call to dlopen could change the value of a symbol that already had a visible definition, an inconsistency which applications could observe. POSIX is unclear whether this should happen or whether it's permitted to happen, but the resolution of Austin Group issue #982 made it formally unspecified. with this patch, a library whose mode is upgraded from local to global enters the symbol lookup order at the point where it was made global, so that symbol resolution before and after the upgrade are consistent. in order to implement this change, the per-dso global flag is replaced with a separate set of linked-list pointers for participation in the global symbol table. this permits the order of dso objects for symbol resolution to differ from the order used for iteration of all loaded libraries. it also improves performance of find_sym, by avoiding a branch per iteration and skipping, and especially in the case where many non-global libraries have been loaded, by allowing the loop to skip over them entirely. logic for temporarily adding non-global libraries to the symbol table for relocation purposes is also mildly simplified.
2017-03-13 01:03:05 +00:00
revert_syms(orig_syms_tail);
for (p=orig_tail->next; p; p=next) {
next = p->next;
while (p->td_index) {
void *tmp = p->td_index->next;
free(p->td_index);
p->td_index = tmp;
}
free(p->funcdescs);
if (p->rpath != p->rpath_orig)
free(p->rpath);
if (p->deps != &nodeps_dummy)
free(p->deps);
unmap_library(p);
free(p);
}
if (!orig_tls_tail) libc.tls_head = 0;
tls_tail = orig_tls_tail;
if (tls_tail) tls_tail->next = 0;
tls_cnt = orig_tls_cnt;
tls_offset = orig_tls_offset;
tls_align = orig_tls_align;
lazy_head = orig_lazy_head;
tail = orig_tail;
tail->next = 0;
p = 0;
goto end;
} else p = load_library(file, head);
if (!p) {
error(noload ?
"Library %s is not already loaded" :
"Error loading shared library %s: %m",
file);
goto end;
}
/* First load handling */
int first_load = !p->deps;
if (first_load) {
load_deps(p);
if (!p->relocated && (mode & RTLD_LAZY)) {
prepare_lazy(p);
for (i=0; p->deps[i]; i++)
if (!p->deps[i]->relocated)
prepare_lazy(p->deps[i]);
}
}
if (first_load || (mode & RTLD_GLOBAL)) {
rework ldso handling of global symbol table for consistency when loading libraries with dlopen, the caller can request that the library's symbols become part of the global symbol table, or that they only be used for resolving relocations in the loaded library and its dependencies. in the latter case, a subsequent dlopen of the same library can upgrade it to global status. previously, if a library was upgraded from local to global mode, its symbols entered the symbol lookup search order at the point where the library was originally loaded. this means that a new call to dlopen could change the value of a symbol that already had a visible definition, an inconsistency which applications could observe. POSIX is unclear whether this should happen or whether it's permitted to happen, but the resolution of Austin Group issue #982 made it formally unspecified. with this patch, a library whose mode is upgraded from local to global enters the symbol lookup order at the point where it was made global, so that symbol resolution before and after the upgrade are consistent. in order to implement this change, the per-dso global flag is replaced with a separate set of linked-list pointers for participation in the global symbol table. this permits the order of dso objects for symbol resolution to differ from the order used for iteration of all loaded libraries. it also improves performance of find_sym, by avoiding a branch per iteration and skipping, and especially in the case where many non-global libraries have been loaded, by allowing the loop to skip over them entirely. logic for temporarily adding non-global libraries to the symbol table for relocation purposes is also mildly simplified.
2017-03-13 01:03:05 +00:00
/* Make new symbols global, at least temporarily, so we can do
* relocations. If not RTLD_GLOBAL, this is reverted below. */
add_syms(p);
for (i=0; p->deps[i]; i++)
rework ldso handling of global symbol table for consistency when loading libraries with dlopen, the caller can request that the library's symbols become part of the global symbol table, or that they only be used for resolving relocations in the loaded library and its dependencies. in the latter case, a subsequent dlopen of the same library can upgrade it to global status. previously, if a library was upgraded from local to global mode, its symbols entered the symbol lookup search order at the point where the library was originally loaded. this means that a new call to dlopen could change the value of a symbol that already had a visible definition, an inconsistency which applications could observe. POSIX is unclear whether this should happen or whether it's permitted to happen, but the resolution of Austin Group issue #982 made it formally unspecified. with this patch, a library whose mode is upgraded from local to global enters the symbol lookup order at the point where it was made global, so that symbol resolution before and after the upgrade are consistent. in order to implement this change, the per-dso global flag is replaced with a separate set of linked-list pointers for participation in the global symbol table. this permits the order of dso objects for symbol resolution to differ from the order used for iteration of all loaded libraries. it also improves performance of find_sym, by avoiding a branch per iteration and skipping, and especially in the case where many non-global libraries have been loaded, by allowing the loop to skip over them entirely. logic for temporarily adding non-global libraries to the symbol table for relocation purposes is also mildly simplified.
2017-03-13 01:03:05 +00:00
add_syms(p->deps[i]);
}
if (first_load) {
reloc_all(p);
}
rework ldso handling of global symbol table for consistency when loading libraries with dlopen, the caller can request that the library's symbols become part of the global symbol table, or that they only be used for resolving relocations in the loaded library and its dependencies. in the latter case, a subsequent dlopen of the same library can upgrade it to global status. previously, if a library was upgraded from local to global mode, its symbols entered the symbol lookup search order at the point where the library was originally loaded. this means that a new call to dlopen could change the value of a symbol that already had a visible definition, an inconsistency which applications could observe. POSIX is unclear whether this should happen or whether it's permitted to happen, but the resolution of Austin Group issue #982 made it formally unspecified. with this patch, a library whose mode is upgraded from local to global enters the symbol lookup order at the point where it was made global, so that symbol resolution before and after the upgrade are consistent. in order to implement this change, the per-dso global flag is replaced with a separate set of linked-list pointers for participation in the global symbol table. this permits the order of dso objects for symbol resolution to differ from the order used for iteration of all loaded libraries. it also improves performance of find_sym, by avoiding a branch per iteration and skipping, and especially in the case where many non-global libraries have been loaded, by allowing the loop to skip over them entirely. logic for temporarily adding non-global libraries to the symbol table for relocation purposes is also mildly simplified.
2017-03-13 01:03:05 +00:00
/* If RTLD_GLOBAL was not specified, undo any new additions
* to the global symbol table. This is a nop if the library was
* previously loaded and already global. */
if (!(mode & RTLD_GLOBAL))
revert_syms(orig_syms_tail);
/* Processing of deferred lazy relocations must not happen until
* the new libraries are committed; otherwise we could end up with
* relocations resolved to symbol definitions that get removed. */
redo_lazy_relocs();
update_tls_size();
_dl_debug_state();
orig_tail = tail;
end:
__release_ptc();
if (p) gencnt++;
pthread_rwlock_unlock(&lock);
if (p) do_init_fini(orig_tail);
pthread_setcancelstate(cs, 0);
return p;
}
hidden int __dl_invalid_handle(void *h)
{
struct dso *p;
for (p=head; p; p=p->next) if (h==p) return 0;
error("Invalid library handle %p", (void *)h);
return 1;
}
static void *addr2dso(size_t a)
{
struct dso *p;
size_t i;
if (DL_FDPIC) for (p=head; p; p=p->next) {
i = count_syms(p);
if (a-(size_t)p->funcdescs < i*sizeof(*p->funcdescs))
return p;
}
for (p=head; p; p=p->next) {
if (DL_FDPIC && p->loadmap) {
for (i=0; i<p->loadmap->nsegs; i++) {
if (a-p->loadmap->segs[i].p_vaddr
< p->loadmap->segs[i].p_memsz)
return p;
}
} else {
Phdr *ph = p->phdr;
size_t phcnt = p->phnum;
size_t entsz = p->phentsize;
size_t base = (size_t)p->base;
for (; phcnt--; ph=(void *)((char *)ph+entsz)) {
if (ph->p_type != PT_LOAD) continue;
if (a-base-ph->p_vaddr < ph->p_memsz)
return p;
}
if (a-(size_t)p->map < p->map_len)
return 0;
}
}
return 0;
}
static void *do_dlsym(struct dso *p, const char *s, void *ra)
{
size_t i;
uint32_t h = 0, gh = 0, *ght;
Sym *sym;
if (p == head || p == RTLD_DEFAULT || p == RTLD_NEXT) {
if (p == RTLD_DEFAULT) {
p = head;
} else if (p == RTLD_NEXT) {
p = addr2dso((size_t)ra);
if (!p) p=head;
p = p->next;
}
struct symdef def = find_sym(p, s, 0);
if (!def.sym) goto failed;
if ((def.sym->st_info&0xf) == STT_TLS)
return __tls_get_addr((tls_mod_off_t []){def.dso->tls_id, def.sym->st_value-DTP_OFFSET});
if (DL_FDPIC && (def.sym->st_info&0xf) == STT_FUNC)
return def.dso->funcdescs + (def.sym - def.dso->syms);
return laddr(def.dso, def.sym->st_value);
}
if (__dl_invalid_handle(p))
return 0;
if ((ght = p->ghashtab)) {
gh = gnu_hash(s);
sym = gnu_lookup(gh, ght, p, s);
} else {
h = sysv_hash(s);
sym = sysv_lookup(s, h, p);
}
if (sym && (sym->st_info&0xf) == STT_TLS)
return __tls_get_addr((tls_mod_off_t []){p->tls_id, sym->st_value-DTP_OFFSET});
if (DL_FDPIC && sym && sym->st_shndx && (sym->st_info&0xf) == STT_FUNC)
return p->funcdescs + (sym - p->syms);
if (sym && sym->st_value && (1<<(sym->st_info&0xf) & OK_TYPES))
return laddr(p, sym->st_value);
for (i=0; p->deps[i]; i++) {
if ((ght = p->deps[i]->ghashtab)) {
if (!gh) gh = gnu_hash(s);
sym = gnu_lookup(gh, ght, p->deps[i], s);
} else {
if (!h) h = sysv_hash(s);
sym = sysv_lookup(s, h, p->deps[i]);
}
if (sym && (sym->st_info&0xf) == STT_TLS)
return __tls_get_addr((tls_mod_off_t []){p->deps[i]->tls_id, sym->st_value-DTP_OFFSET});
if (DL_FDPIC && sym && sym->st_shndx && (sym->st_info&0xf) == STT_FUNC)
return p->deps[i]->funcdescs + (sym - p->deps[i]->syms);
if (sym && sym->st_value && (1<<(sym->st_info&0xf) & OK_TYPES))
return laddr(p->deps[i], sym->st_value);
}
failed:
error("Symbol not found: %s", s);
return 0;
}
int dladdr(const void *addr_arg, Dl_info *info)
{
size_t addr = (size_t)addr_arg;
struct dso *p;
Sym *sym, *bestsym;
uint32_t nsym;
char *strings;
size_t best = 0;
size_t besterr = -1;
pthread_rwlock_rdlock(&lock);
p = addr2dso(addr);
pthread_rwlock_unlock(&lock);
if (!p) return 0;
sym = p->syms;
strings = p->strings;
nsym = count_syms(p);
if (DL_FDPIC) {
size_t idx = (addr-(size_t)p->funcdescs)
/ sizeof(*p->funcdescs);
if (idx < nsym && (sym[idx].st_info&0xf) == STT_FUNC) {
best = (size_t)(p->funcdescs + idx);
bestsym = sym + idx;
besterr = 0;
}
}
if (!best) for (; nsym; nsym--, sym++) {
if (sym->st_value
&& (1<<(sym->st_info&0xf) & OK_TYPES)
&& (1<<(sym->st_info>>4) & OK_BINDS)) {
size_t symaddr = (size_t)laddr(p, sym->st_value);
if (symaddr > addr || symaddr <= best)
continue;
best = symaddr;
bestsym = sym;
besterr = addr - symaddr;
if (addr == symaddr)
break;
}
}
if (bestsym && besterr > bestsym->st_size-1) {
best = 0;
bestsym = 0;
}
info->dli_fname = p->name;
info->dli_fbase = p->map;
if (!best) {
info->dli_sname = 0;
info->dli_saddr = 0;
return 1;
}
if (DL_FDPIC && (bestsym->st_info&0xf) == STT_FUNC)
best = (size_t)(p->funcdescs + (bestsym - p->syms));
info->dli_sname = strings + bestsym->st_name;
info->dli_saddr = (void *)best;
return 1;
}
hidden void *__dlsym(void *restrict p, const char *restrict s, void *restrict ra)
{
void *res;
pthread_rwlock_rdlock(&lock);
res = do_dlsym(p, s, ra);
pthread_rwlock_unlock(&lock);
return res;
}
int dl_iterate_phdr(int(*callback)(struct dl_phdr_info *info, size_t size, void *data), void *data)
{
struct dso *current;
struct dl_phdr_info info;
int ret = 0;
for(current = head; current;) {
info.dlpi_addr = (uintptr_t)current->base;
info.dlpi_name = current->name;
info.dlpi_phdr = current->phdr;
info.dlpi_phnum = current->phnum;
info.dlpi_adds = gencnt;
info.dlpi_subs = 0;
info.dlpi_tls_modid = current->tls_id;
info.dlpi_tls_data = current->tls.image;
ret = (callback)(&info, sizeof (info), data);
if (ret != 0) break;
pthread_rwlock_rdlock(&lock);
current = current->next;
pthread_rwlock_unlock(&lock);
}
return ret;
}
static void error(const char *fmt, ...)
{
va_list ap;
va_start(ap, fmt);
if (!runtime) {
vdprintf(2, fmt, ap);
dprintf(2, "\n");
ldso_fail = 1;
va_end(ap);
return;
}
__dl_vseterr(fmt, ap);
va_end(ap);
}