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15a0c5730d
This second patch contains the actual implementation of a new sorting algorithm for shared objects in the dynamic loader, which solves the slow behavior that the current "old" algorithm falls into when the DSO set contains circular dependencies. The new algorithm implemented here is simply depth-first search (DFS) to obtain the Reverse-Post Order (RPO) sequence, a topological sort. A new l_visited:1 bitfield is added to struct link_map to more elegantly facilitate such a search. The DFS algorithm is applied to the input maps[nmap-1] backwards towards maps[0]. This has the effect of a more "shallow" recursion depth in general since the input is in BFS. Also, when combined with the natural order of processing l_initfini[] at each node, this creates a resulting output sorting closer to the intuitive "left-to-right" order in most cases. Another notable implementation adjustment related to this _dl_sort_maps change is the removing of two char arrays 'used' and 'done' in _dl_close_worker to represent two per-map attributes. This has been changed to simply use two new bit-fields l_map_used:1, l_map_done:1 added to struct link_map. This also allows discarding the clunky 'used' array sorting that _dl_sort_maps had to sometimes do along the way. Tunable support for switching between different sorting algorithms at runtime is also added. A new tunable 'glibc.rtld.dynamic_sort' with current valid values 1 (old algorithm) and 2 (new DFS algorithm) has been added. At time of commit of this patch, the default setting is 1 (old algorithm). Signed-off-by: Chung-Lin Tang <cltang@codesourcery.com> Reviewed-by: Adhemerval Zanella <adhemerval.zanella@linaro.org>
188 lines
6.0 KiB
C
188 lines
6.0 KiB
C
/* Call the termination functions of loaded shared objects.
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Copyright (C) 1995-2021 Free Software Foundation, Inc.
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This file is part of the GNU C Library.
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The GNU C Library is free software; you can redistribute it and/or
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modify it under the terms of the GNU Lesser General Public
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License as published by the Free Software Foundation; either
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version 2.1 of the License, or (at your option) any later version.
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The GNU C Library is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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Lesser General Public License for more details.
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You should have received a copy of the GNU Lesser General Public
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License along with the GNU C Library; if not, see
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<https://www.gnu.org/licenses/>. */
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#include <assert.h>
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#include <string.h>
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#include <ldsodefs.h>
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#include <elf-initfini.h>
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/* Type of the constructor functions. */
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typedef void (*fini_t) (void);
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void
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_dl_fini (void)
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{
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/* Lots of fun ahead. We have to call the destructors for all still
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loaded objects, in all namespaces. The problem is that the ELF
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specification now demands that dependencies between the modules
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are taken into account. I.e., the destructor for a module is
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called before the ones for any of its dependencies.
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To make things more complicated, we cannot simply use the reverse
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order of the constructors. Since the user might have loaded objects
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using `dlopen' there are possibly several other modules with its
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dependencies to be taken into account. Therefore we have to start
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determining the order of the modules once again from the beginning. */
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/* We run the destructors of the main namespaces last. As for the
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other namespaces, we pick run the destructors in them in reverse
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order of the namespace ID. */
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#ifdef SHARED
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int do_audit = 0;
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again:
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#endif
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for (Lmid_t ns = GL(dl_nns) - 1; ns >= 0; --ns)
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{
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/* Protect against concurrent loads and unloads. */
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__rtld_lock_lock_recursive (GL(dl_load_lock));
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unsigned int nloaded = GL(dl_ns)[ns]._ns_nloaded;
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/* No need to do anything for empty namespaces or those used for
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auditing DSOs. */
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if (nloaded == 0
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#ifdef SHARED
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|| GL(dl_ns)[ns]._ns_loaded->l_auditing != do_audit
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#endif
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)
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__rtld_lock_unlock_recursive (GL(dl_load_lock));
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else
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{
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/* Now we can allocate an array to hold all the pointers and
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copy the pointers in. */
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struct link_map *maps[nloaded];
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unsigned int i;
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struct link_map *l;
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assert (nloaded != 0 || GL(dl_ns)[ns]._ns_loaded == NULL);
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for (l = GL(dl_ns)[ns]._ns_loaded, i = 0; l != NULL; l = l->l_next)
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/* Do not handle ld.so in secondary namespaces. */
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if (l == l->l_real)
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{
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assert (i < nloaded);
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maps[i] = l;
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l->l_idx = i;
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++i;
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/* Bump l_direct_opencount of all objects so that they
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are not dlclose()ed from underneath us. */
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++l->l_direct_opencount;
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}
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assert (ns != LM_ID_BASE || i == nloaded);
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assert (ns == LM_ID_BASE || i == nloaded || i == nloaded - 1);
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unsigned int nmaps = i;
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/* Now we have to do the sorting. We can skip looking for the
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binary itself which is at the front of the search list for
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the main namespace. */
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_dl_sort_maps (maps, nmaps, (ns == LM_ID_BASE), true);
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/* We do not rely on the linked list of loaded object anymore
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from this point on. We have our own list here (maps). The
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various members of this list cannot vanish since the open
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count is too high and will be decremented in this loop. So
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we release the lock so that some code which might be called
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from a destructor can directly or indirectly access the
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lock. */
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__rtld_lock_unlock_recursive (GL(dl_load_lock));
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/* 'maps' now contains the objects in the right order. Now
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call the destructors. We have to process this array from
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the front. */
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for (i = 0; i < nmaps; ++i)
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{
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struct link_map *l = maps[i];
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if (l->l_init_called)
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{
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/* Make sure nothing happens if we are called twice. */
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l->l_init_called = 0;
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/* Is there a destructor function? */
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if (l->l_info[DT_FINI_ARRAY] != NULL
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|| (ELF_INITFINI && l->l_info[DT_FINI] != NULL))
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{
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/* When debugging print a message first. */
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if (__builtin_expect (GLRO(dl_debug_mask)
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& DL_DEBUG_IMPCALLS, 0))
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_dl_debug_printf ("\ncalling fini: %s [%lu]\n\n",
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DSO_FILENAME (l->l_name),
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ns);
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/* First see whether an array is given. */
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if (l->l_info[DT_FINI_ARRAY] != NULL)
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{
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ElfW(Addr) *array =
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(ElfW(Addr) *) (l->l_addr
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+ l->l_info[DT_FINI_ARRAY]->d_un.d_ptr);
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unsigned int i = (l->l_info[DT_FINI_ARRAYSZ]->d_un.d_val
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/ sizeof (ElfW(Addr)));
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while (i-- > 0)
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((fini_t) array[i]) ();
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}
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/* Next try the old-style destructor. */
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if (ELF_INITFINI && l->l_info[DT_FINI] != NULL)
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DL_CALL_DT_FINI
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(l, l->l_addr + l->l_info[DT_FINI]->d_un.d_ptr);
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}
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#ifdef SHARED
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/* Auditing checkpoint: another object closed. */
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if (!do_audit && __builtin_expect (GLRO(dl_naudit) > 0, 0))
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{
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struct audit_ifaces *afct = GLRO(dl_audit);
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for (unsigned int cnt = 0; cnt < GLRO(dl_naudit); ++cnt)
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{
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if (afct->objclose != NULL)
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{
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struct auditstate *state
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= link_map_audit_state (l, cnt);
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/* Return value is ignored. */
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(void) afct->objclose (&state->cookie);
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}
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afct = afct->next;
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}
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}
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#endif
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}
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/* Correct the previous increment. */
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--l->l_direct_opencount;
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}
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}
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}
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#ifdef SHARED
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if (! do_audit && GLRO(dl_naudit) > 0)
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{
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do_audit = 1;
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goto again;
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}
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if (__glibc_unlikely (GLRO(dl_debug_mask) & DL_DEBUG_STATISTICS))
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_dl_debug_printf ("\nruntime linker statistics:\n"
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" final number of relocations: %lu\n"
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"final number of relocations from cache: %lu\n",
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GL(dl_num_relocations),
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GL(dl_num_cache_relocations));
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#endif
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}
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