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33237fe83d
And make always supported. The configure option was added on glibc 2.25 and some features require it (such as hwcap mask, huge pages support, and lock elisition tuning). It also simplifies the build permutations. Changes from v1: * Remove glibc.rtld.dynamic_sort changes, it is orthogonal and needs more discussion. * Cleanup more code. Reviewed-by: Siddhesh Poyarekar <siddhesh@sourceware.org>
312 lines
10 KiB
C
312 lines
10 KiB
C
/* Sort array of link maps according to dependencies.
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Copyright (C) 2017-2023 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 <ldsodefs.h>
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#include <elf/dl-tunables.h>
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/* Note: this is the older, "original" sorting algorithm, being used as
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default up to 2.35.
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Sort array MAPS according to dependencies of the contained objects.
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If FOR_FINI is true, this is called for finishing an object. */
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static void
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_dl_sort_maps_original (struct link_map **maps, unsigned int nmaps,
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bool force_first, bool for_fini)
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{
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/* Allows caller to do the common optimization of skipping the first map,
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usually the main binary. */
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maps += force_first;
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nmaps -= force_first;
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/* A list of one element need not be sorted. */
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if (nmaps <= 1)
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return;
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unsigned int i = 0;
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uint16_t seen[nmaps];
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memset (seen, 0, nmaps * sizeof (seen[0]));
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while (1)
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{
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/* Keep track of which object we looked at this round. */
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++seen[i];
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struct link_map *thisp = maps[i];
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if (__glibc_unlikely (for_fini))
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{
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/* Do not handle ld.so in secondary namespaces and objects which
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are not removed. */
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if (thisp != thisp->l_real || thisp->l_idx == -1)
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goto skip;
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}
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/* Find the last object in the list for which the current one is
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a dependency and move the current object behind the object
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with the dependency. */
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unsigned int k = nmaps - 1;
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while (k > i)
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{
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struct link_map **runp = maps[k]->l_initfini;
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if (runp != NULL)
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/* Look through the dependencies of the object. */
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while (*runp != NULL)
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if (__glibc_unlikely (*runp++ == thisp))
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{
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move:
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/* Move the current object to the back past the last
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object with it as the dependency. */
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memmove (&maps[i], &maps[i + 1],
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(k - i) * sizeof (maps[0]));
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maps[k] = thisp;
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if (seen[i + 1] > nmaps - i)
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{
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++i;
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goto next_clear;
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}
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uint16_t this_seen = seen[i];
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memmove (&seen[i], &seen[i + 1], (k - i) * sizeof (seen[0]));
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seen[k] = this_seen;
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goto next;
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}
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if (__glibc_unlikely (for_fini && maps[k]->l_reldeps != NULL))
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{
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unsigned int m = maps[k]->l_reldeps->act;
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struct link_map **relmaps = &maps[k]->l_reldeps->list[0];
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/* Look through the relocation dependencies of the object. */
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while (m-- > 0)
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if (__glibc_unlikely (relmaps[m] == thisp))
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{
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/* If a cycle exists with a link time dependency,
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preserve the latter. */
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struct link_map **runp = thisp->l_initfini;
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if (runp != NULL)
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while (*runp != NULL)
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if (__glibc_unlikely (*runp++ == maps[k]))
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goto ignore;
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goto move;
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}
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ignore:;
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}
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--k;
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}
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skip:
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if (++i == nmaps)
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break;
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next_clear:
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memset (&seen[i], 0, (nmaps - i) * sizeof (seen[0]));
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next:;
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}
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}
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/* We use a recursive function due to its better clarity and ease of
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implementation, as well as faster execution speed. We already use
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alloca() for list allocation during the breadth-first search of
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dependencies in _dl_map_object_deps(), and this should be on the
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same order of worst-case stack usage.
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Note: the '*rpo' parameter is supposed to point to one past the
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last element of the array where we save the sort results, and is
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decremented before storing the current map at each level. */
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static void
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dfs_traversal (struct link_map ***rpo, struct link_map *map,
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bool *do_reldeps)
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{
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/* _dl_map_object_deps ignores l_faked objects when calculating the
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number of maps before calling _dl_sort_maps, ignore them as well. */
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if (map->l_visited || map->l_faked)
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return;
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map->l_visited = 1;
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if (map->l_initfini)
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{
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for (int i = 0; map->l_initfini[i] != NULL; i++)
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{
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struct link_map *dep = map->l_initfini[i];
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if (dep->l_visited == 0
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&& dep->l_main_map == 0)
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dfs_traversal (rpo, dep, do_reldeps);
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}
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}
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if (__glibc_unlikely (do_reldeps != NULL && map->l_reldeps != NULL))
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{
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/* Indicate that we encountered relocation dependencies during
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traversal. */
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*do_reldeps = true;
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for (int m = map->l_reldeps->act - 1; m >= 0; m--)
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{
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struct link_map *dep = map->l_reldeps->list[m];
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if (dep->l_visited == 0
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&& dep->l_main_map == 0)
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dfs_traversal (rpo, dep, do_reldeps);
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}
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}
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*rpo -= 1;
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**rpo = map;
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}
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/* Topologically sort array MAPS according to dependencies of the contained
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objects. */
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static void
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_dl_sort_maps_dfs (struct link_map **maps, unsigned int nmaps,
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bool force_first, bool for_fini)
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{
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struct link_map *first_map = maps[0];
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for (int i = nmaps - 1; i >= 0; i--)
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maps[i]->l_visited = 0;
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/* We apply DFS traversal for each of maps[i] until the whole total order
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is found and we're at the start of the Reverse-Postorder (RPO) sequence,
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which is a topological sort.
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We go from maps[nmaps - 1] backwards towards maps[0] at this level.
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Due to the breadth-first search (BFS) ordering we receive, going
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backwards usually gives a more shallow depth-first recursion depth,
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adding more stack usage safety. Also, combined with the natural
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processing order of l_initfini[] at each node during DFS, this maintains
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an ordering closer to the original link ordering in the sorting results
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under most simpler cases.
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Another reason we order the top level backwards, it that maps[0] is
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usually exactly the main object of which we're in the midst of
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_dl_map_object_deps() processing, and maps[0]->l_initfini[] is still
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blank. If we start the traversal from maps[0], since having no
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dependencies yet filled in, maps[0] will always be immediately
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incorrectly placed at the last place in the order (first in reverse).
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Adjusting the order so that maps[0] is last traversed naturally avoids
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this problem.
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To summarize, just passing in the full list, and iterating from back
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to front makes things much more straightforward. */
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/* Array to hold RPO sorting results, before we copy back to maps[]. */
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struct link_map *rpo[nmaps];
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/* The 'head' position during each DFS iteration. Note that we start at
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one past the last element due to first-decrement-then-store (see the
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bottom of above dfs_traversal() routine). */
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struct link_map **rpo_head = &rpo[nmaps];
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bool do_reldeps = false;
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bool *do_reldeps_ref = (for_fini ? &do_reldeps : NULL);
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for (int i = nmaps - 1; i >= 0; i--)
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{
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dfs_traversal (&rpo_head, maps[i], do_reldeps_ref);
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/* We can break early if all objects are already placed. */
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if (rpo_head == rpo)
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goto end;
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}
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assert (rpo_head == rpo);
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end:
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/* Here we may do a second pass of sorting, using only l_initfini[]
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static dependency links. This is avoided if !FOR_FINI or if we didn't
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find any reldeps in the first DFS traversal.
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The reason we do this is: while it is unspecified how circular
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dependencies should be handled, the presumed reasonable behavior is to
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have destructors to respect static dependency links as much as possible,
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overriding reldeps if needed. And the first sorting pass, which takes
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l_initfini/l_reldeps links equally, may not preserve this priority.
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Hence we do a 2nd sorting pass, taking only DT_NEEDED links into account
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(see how the do_reldeps argument to dfs_traversal() is NULL below). */
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if (do_reldeps)
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{
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for (int i = nmaps - 1; i >= 0; i--)
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rpo[i]->l_visited = 0;
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struct link_map **maps_head = &maps[nmaps];
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for (int i = nmaps - 1; i >= 0; i--)
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{
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dfs_traversal (&maps_head, rpo[i], NULL);
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/* We can break early if all objects are already placed.
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The below memcpy is not needed in the do_reldeps case here,
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since we wrote back to maps[] during DFS traversal. */
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if (maps_head == maps)
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return;
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}
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assert (maps_head == maps);
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return;
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}
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memcpy (maps, rpo, sizeof (struct link_map *) * nmaps);
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/* Skipping the first object at maps[0] is not valid in general,
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since traversing along object dependency-links may "find" that
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first object even when it is not included in the initial order
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(e.g., a dlopen'ed shared object can have circular dependencies
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linked back to itself). In such a case, traversing N-1 objects
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will create a N-object result, and raise problems. Instead,
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force the object back into first place after sorting. This naive
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approach may introduce further dependency ordering violations
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compared to rotating the cycle until the first map is again in
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the first position, but as there is a cycle, at least one
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violation is already present. */
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if (force_first && maps[0] != first_map)
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{
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int i;
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for (i = 0; maps[i] != first_map; ++i)
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;
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assert (i < nmaps);
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memmove (&maps[1], maps, i * sizeof (maps[0]));
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maps[0] = first_map;
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}
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}
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void
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_dl_sort_maps_init (void)
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{
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int32_t algorithm = TUNABLE_GET (glibc, rtld, dynamic_sort, int32_t, NULL);
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GLRO(dl_dso_sort_algo) = algorithm == 1 ? dso_sort_algorithm_original
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: dso_sort_algorithm_dfs;
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}
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void
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_dl_sort_maps (struct link_map **maps, unsigned int nmaps,
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bool force_first, bool for_fini)
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{
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/* It can be tempting to use a static function pointer to store and call
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the current selected sorting algorithm routine, but experimentation
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shows that current processors still do not handle indirect branches
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that efficiently, plus a static function pointer will involve
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PTR_MANGLE/DEMANGLE, further impairing performance of small, common
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input cases. A simple if-case with direct function calls appears to
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be the fastest. */
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if (__glibc_likely (GLRO(dl_dso_sort_algo) == dso_sort_algorithm_original))
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_dl_sort_maps_original (maps, nmaps, force_first, for_fini);
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else
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_dl_sort_maps_dfs (maps, nmaps, force_first, for_fini);
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}
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