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2fa4b6e6df
Three new functions for looking up the enum type containing a given enumeration constant, and optionally that constant's value. The simplest, ctf_lookup_enumerator, looks up a root-visible enumerator by name in one dict: if the dict contains multiple such constants (which is possible for dicts created by older versions of the libctf deduplicator), ECTF_DUPLICATE is returned. The next simplest, ctf_lookup_enumerator_next, is an iterator which returns all enumerators with a given name in a given dict, whether root-visible or not. The most elaborate, ctf_arc_lookup_enumerator_next, finds all enumerators with a given name across all dicts in an entire CTF archive, whether root-visible or not, starting looking in the shared parent dict; opened dicts are cached (as with all other ctf_arc_*lookup functions) so that repeated use does not incur repeated opening costs. All three of these return enumerator values as int64_t: unfortunately, API compatibility concerns prevent us from doing the same with the other older enum-related functions, which all return enumerator constant values as ints. We may be forced to add symbol-versioning compatibility aliases that fix the other functions in due course, bumping the soname for platforms that do not support such things. ctf_arc_lookup_enumerator_next is implemented as a nested ctf_archive_next iterator, and inside that, a nested ctf_lookup_enumerator_next iterator within each dict. To aid in this, add support to ctf_next_t iterators for iterators that are implemented in terms of two simultaneous nested iterators at once. (It has always been possible for callers to use as many nested or semi-overlapping ctf_next_t iterators as they need, which is one of the advantages of this style over the _iter style that calls a function for each thing iterated over: the iterator change here permits *ctf_next_t iterators themselves* to be implemented by iterating using multiple other iterators as part of their internal operation, transparently to the caller.) Also add a testcase that tests all these functions (which is fairly easy because ctf_arc_lookup_enumerator_next is implemented in terms of ctf_lookup_enumerator_next) in addition to enumeration addition in ctf_open()ed dicts, ctf_add_enumerator duplicate enumerator addition, and conflicting enumerator constant deduplication. include/ * ctf-api.h (ctf_lookup_enumerator): New. (ctf_lookup_enumerator_next): Likewise. (ctf_arc_lookup_enumerator_next): Likewise. libctf/ * libctf.ver: Add them. * ctf-impl.h (ctf_next_t) <ctn_next_inner>: New. * ctf-util.c (ctf_next_copy): Copy it. (ctf_next_destroy): Destroy it. * ctf-lookup.c (ctf_lookup_enumerator): New. (ctf_lookup_enumerator_next): New. * ctf-archive.c (ctf_arc_lookup_enumerator_next): New. * testsuite/libctf-lookup/enumerator-iteration.*: New test. * testsuite/libctf-lookup/enum-ctf-2.c: New test CTF, used by the above.
313 lines
7.4 KiB
C
313 lines
7.4 KiB
C
/* Miscellaneous utilities.
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Copyright (C) 2019-2024 Free Software Foundation, Inc.
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This file is part of libctf.
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libctf is free software; you can redistribute it and/or modify it under
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the terms of the GNU General Public License as published by the Free
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Software Foundation; either version 3, or (at your option) any later
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version.
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This program is distributed in the hope that it will be useful, but
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WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
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See the GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; see the file COPYING. If not see
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<http://www.gnu.org/licenses/>. */
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#include <ctf-impl.h>
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#include <string.h>
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#include "ctf-endian.h"
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/* Simple doubly-linked list append routine. This implementation assumes that
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each list element contains an embedded ctf_list_t as the first member.
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An additional ctf_list_t is used to store the head (l_next) and tail
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(l_prev) pointers. The current head and tail list elements have their
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previous and next pointers set to NULL, respectively. */
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void
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ctf_list_append (ctf_list_t *lp, void *newp)
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{
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ctf_list_t *p = lp->l_prev; /* p = tail list element. */
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ctf_list_t *q = newp; /* q = new list element. */
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lp->l_prev = q;
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q->l_prev = p;
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q->l_next = NULL;
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if (p != NULL)
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p->l_next = q;
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else
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lp->l_next = q;
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}
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/* Prepend the specified existing element to the given ctf_list_t. The
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existing pointer should be pointing at a struct with embedded ctf_list_t. */
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void
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ctf_list_prepend (ctf_list_t * lp, void *newp)
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{
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ctf_list_t *p = newp; /* p = new list element. */
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ctf_list_t *q = lp->l_next; /* q = head list element. */
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lp->l_next = p;
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p->l_prev = NULL;
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p->l_next = q;
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if (q != NULL)
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q->l_prev = p;
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else
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lp->l_prev = p;
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}
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/* Delete the specified existing element from the given ctf_list_t. The
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existing pointer should be pointing at a struct with embedded ctf_list_t. */
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void
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ctf_list_delete (ctf_list_t *lp, void *existing)
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{
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ctf_list_t *p = existing;
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if (p->l_prev != NULL)
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p->l_prev->l_next = p->l_next;
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else
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lp->l_next = p->l_next;
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if (p->l_next != NULL)
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p->l_next->l_prev = p->l_prev;
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else
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lp->l_prev = p->l_prev;
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}
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/* Return 1 if the list is empty. */
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int
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ctf_list_empty_p (ctf_list_t *lp)
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{
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return (lp->l_next == NULL && lp->l_prev == NULL);
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}
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/* Splice one entire list onto the end of another one. The existing list is
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emptied. */
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void
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ctf_list_splice (ctf_list_t *lp, ctf_list_t *append)
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{
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if (ctf_list_empty_p (append))
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return;
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if (lp->l_prev != NULL)
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lp->l_prev->l_next = append->l_next;
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else
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lp->l_next = append->l_next;
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append->l_next->l_prev = lp->l_prev;
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lp->l_prev = append->l_prev;
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append->l_next = NULL;
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append->l_prev = NULL;
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}
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/* Convert a 32-bit ELF symbol to a ctf_link_sym_t. */
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ctf_link_sym_t *
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ctf_elf32_to_link_sym (ctf_dict_t *fp, ctf_link_sym_t *dst, const Elf32_Sym *src,
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uint32_t symidx)
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{
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Elf32_Sym tmp;
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int needs_flipping = 0;
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#ifdef WORDS_BIGENDIAN
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if (fp->ctf_symsect_little_endian)
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needs_flipping = 1;
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#else
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if (!fp->ctf_symsect_little_endian)
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needs_flipping = 1;
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#endif
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memcpy (&tmp, src, sizeof (Elf32_Sym));
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if (needs_flipping)
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{
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swap_thing (tmp.st_name);
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swap_thing (tmp.st_size);
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swap_thing (tmp.st_shndx);
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swap_thing (tmp.st_value);
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}
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/* The name must be in the external string table. */
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if (tmp.st_name < fp->ctf_str[CTF_STRTAB_1].cts_len)
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dst->st_name = (const char *) fp->ctf_str[CTF_STRTAB_1].cts_strs + tmp.st_name;
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else
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dst->st_name = _CTF_NULLSTR;
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dst->st_nameidx_set = 0;
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dst->st_symidx = symidx;
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dst->st_shndx = tmp.st_shndx;
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dst->st_type = ELF32_ST_TYPE (tmp.st_info);
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dst->st_value = tmp.st_value;
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return dst;
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}
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/* Convert a 64-bit ELF symbol to a ctf_link_sym_t. */
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ctf_link_sym_t *
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ctf_elf64_to_link_sym (ctf_dict_t *fp, ctf_link_sym_t *dst, const Elf64_Sym *src,
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uint32_t symidx)
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{
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Elf64_Sym tmp;
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int needs_flipping = 0;
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#ifdef WORDS_BIGENDIAN
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if (fp->ctf_symsect_little_endian)
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needs_flipping = 1;
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#else
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if (!fp->ctf_symsect_little_endian)
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needs_flipping = 1;
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#endif
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memcpy (&tmp, src, sizeof (Elf64_Sym));
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if (needs_flipping)
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{
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swap_thing (tmp.st_name);
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swap_thing (tmp.st_size);
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swap_thing (tmp.st_shndx);
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swap_thing (tmp.st_value);
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}
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/* The name must be in the external string table. */
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if (tmp.st_name < fp->ctf_str[CTF_STRTAB_1].cts_len)
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dst->st_name = (const char *) fp->ctf_str[CTF_STRTAB_1].cts_strs + tmp.st_name;
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else
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dst->st_name = _CTF_NULLSTR;
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dst->st_nameidx_set = 0;
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dst->st_symidx = symidx;
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dst->st_shndx = tmp.st_shndx;
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dst->st_type = ELF32_ST_TYPE (tmp.st_info);
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/* We only care if the value is zero, so avoid nonzeroes turning into
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zeroes. */
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if (_libctf_unlikely_ (tmp.st_value != 0 && ((uint32_t) tmp.st_value == 0)))
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dst->st_value = 1;
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else
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dst->st_value = (uint32_t) tmp.st_value;
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return dst;
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}
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/* A string appender working on dynamic strings. Returns NULL on OOM. */
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char *
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ctf_str_append (char *s, const char *append)
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{
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size_t s_len = 0;
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if (append == NULL)
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return s;
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if (s != NULL)
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s_len = strlen (s);
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size_t append_len = strlen (append);
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if ((s = realloc (s, s_len + append_len + 1)) == NULL)
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return NULL;
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memcpy (s + s_len, append, append_len);
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s[s_len + append_len] = '\0';
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return s;
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}
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/* A version of ctf_str_append that returns the old string on OOM. */
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char *
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ctf_str_append_noerr (char *s, const char *append)
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{
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char *new_s;
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new_s = ctf_str_append (s, append);
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if (!new_s)
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return s;
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return new_s;
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}
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/* Store the specified error code into errp if it is non-NULL, and then
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return NULL for the benefit of the caller. */
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void *
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ctf_set_open_errno (int *errp, int error)
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{
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if (errp != NULL)
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*errp = error;
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return NULL;
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}
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/* Create a ctf_next_t. */
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ctf_next_t *
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ctf_next_create (void)
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{
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return calloc (1, sizeof (struct ctf_next));
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}
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/* Destroy a ctf_next_t, for early exit from iterators. */
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void
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ctf_next_destroy (ctf_next_t *i)
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{
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if (i == NULL)
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return;
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if (i->ctn_iter_fun == (void (*) (void)) ctf_dynhash_next_sorted)
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free (i->u.ctn_sorted_hkv);
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if (i->ctn_next)
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ctf_next_destroy (i->ctn_next);
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if (i->ctn_next_inner)
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ctf_next_destroy (i->ctn_next_inner);
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free (i);
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}
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/* Copy a ctf_next_t. */
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ctf_next_t *
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ctf_next_copy (ctf_next_t *i)
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{
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ctf_next_t *i2;
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if ((i2 = ctf_next_create()) == NULL)
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return NULL;
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memcpy (i2, i, sizeof (struct ctf_next));
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if (i2->ctn_next)
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{
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i2->ctn_next = ctf_next_copy (i2->ctn_next);
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if (i2->ctn_next == NULL)
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goto err_next;
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}
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if (i2->ctn_next_inner)
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{
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i2->ctn_next_inner = ctf_next_copy (i2->ctn_next_inner);
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if (i2->ctn_next_inner == NULL)
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goto err_next_inner;
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}
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if (i2->ctn_iter_fun == (void (*) (void)) ctf_dynhash_next_sorted)
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{
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size_t els = ctf_dynhash_elements ((ctf_dynhash_t *) i->cu.ctn_h);
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if ((i2->u.ctn_sorted_hkv = calloc (els, sizeof (ctf_next_hkv_t))) == NULL)
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goto err_sorted_hkv;
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memcpy (i2->u.ctn_sorted_hkv, i->u.ctn_sorted_hkv,
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els * sizeof (ctf_next_hkv_t));
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}
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return i2;
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err_sorted_hkv:
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ctf_next_destroy (i2->ctn_next_inner);
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err_next_inner:
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ctf_next_destroy (i2->ctn_next);
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err_next:
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ctf_next_destroy (i2);
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return NULL;
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}
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