/src/libbpf/elfutils/libelf/version_xlate.h

Source
/* Conversion functions for versioning information.
   Copyright (C) 1998, 1999, 2000, 2002, 2003, 2015 Red Hat, Inc.
   Copyright (C) 2022 Mark J. Wielaard <mark@klomp.org>
   This file is part of elfutils.
   Written by Ulrich Drepper <drepper@redhat.com>, 1998.

   This file is free software; you can redistribute it and/or modify
   it under the terms of either

     * the GNU Lesser General Public License as published by the Free
       Software Foundation; either version 3 of the License, or (at
       your option) any later version

   or

     * the GNU General Public License as published by the Free
       Software Foundation; either version 2 of the License, or (at
       your option) any later version

   or both in parallel, as here.

   elfutils is distributed in the hope that it will be useful, but
   WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
   General Public License for more details.

   You should have received copies of the GNU General Public License and
   the GNU Lesser General Public License along with this program.  If
   not, see <http://www.gnu.org/licenses/>.  */

#include <assert.h>
#include <gelf.h>

#include "libelfP.h"


static void
elf_cvt_Verdef (void *dest, const void *src, size_t len, int encode)
{
  /* We have two different record types: ElfXX_Verndef and ElfXX_Verdaux.
     To recognize them we have to walk the data structure and convert
     them one after the other.  The ENCODE parameter specifies whether
     we are encoding or decoding.  When we are encoding we can immediately
     use the data in the buffer; if not, we have to decode the data before
     using it.  */
  size_t def_offset = 0;
  GElf_Verdef *ddest;
  GElf_Verdef *dsrc;

  /* We rely on the types being all the same size.  */
  assert (sizeof (GElf_Verdef) == sizeof (Elf32_Verdef));
  assert (sizeof (GElf_Verdaux) == sizeof (Elf32_Verdaux));
  assert (sizeof (GElf_Verdef) == sizeof (Elf64_Verdef));
  assert (sizeof (GElf_Verdaux) == sizeof (Elf64_Verdaux));

  if (len == 0)
    return;

  /* Below we rely on the next field offsets to be correct, start by
     copying over all data as is in case some data isn't translated.
     We don't want to leave (undefined) garbage in the dest buffer.  */
  memmove (dest, src, len);

  do
    {
      size_t aux_offset;
      GElf_Verdaux *asrc;

      /* Test for correct offset.  */
      if (def_offset > len
    || len - def_offset < sizeof (GElf_Verdef)
    || (def_offset & (__alignof__ (GElf_Verdef) - 1)) != 0)
  return;

      /* Work the tree from the first record.  */
      ddest = (GElf_Verdef *) ((char *) dest + def_offset);
      dsrc = (GElf_Verdef *) ((char *) src + def_offset);

      /* Decode first if necessary.  */
      if (! encode)
  {
    ddest->vd_version = bswap_16 (dsrc->vd_version);
    ddest->vd_flags = bswap_16 (dsrc->vd_flags);
    ddest->vd_ndx = bswap_16 (dsrc->vd_ndx);
    ddest->vd_cnt = bswap_16 (dsrc->vd_cnt);
    ddest->vd_hash = bswap_32 (dsrc->vd_hash);
    ddest->vd_aux = bswap_32 (dsrc->vd_aux);
    ddest->vd_next = bswap_32 (dsrc->vd_next);

    if (ddest->vd_aux > len - def_offset)
      return;
    aux_offset = def_offset + ddest->vd_aux;
  }
      else
  {
    if (dsrc->vd_aux > len - def_offset)
      return;
    aux_offset = def_offset + dsrc->vd_aux;
  }

      /* Handle all the auxiliary records belonging to this definition.  */
      do
  {
    GElf_Verdaux *adest;

    /* Test for correct offset.  */
    if (aux_offset > len
        || len - aux_offset < sizeof (GElf_Verdaux)
        || (aux_offset & (__alignof__ (GElf_Verdaux) - 1)) != 0)
      return;

    adest = (GElf_Verdaux *) ((char *) dest + aux_offset);
    asrc = (GElf_Verdaux *) ((char *) src + aux_offset);

    if (encode)
      {
        if (asrc->vda_next > len - aux_offset)
    return;
        aux_offset += asrc->vda_next;
      }

    adest->vda_name = bswap_32 (asrc->vda_name);
    adest->vda_next = bswap_32 (asrc->vda_next);

    if (! encode)
      {
        if (adest->vda_next > len - aux_offset)
    return;
        aux_offset += adest->vda_next;
      }
  }
      while (asrc->vda_next != 0);

      /* Encode now if necessary.  */
      if (encode)
  {
    if (dsrc->vd_next > len - def_offset)
      return;
    def_offset += dsrc->vd_next;

    ddest->vd_version = bswap_16 (dsrc->vd_version);
    ddest->vd_flags = bswap_16 (dsrc->vd_flags);
    ddest->vd_ndx = bswap_16 (dsrc->vd_ndx);
    ddest->vd_cnt = bswap_16 (dsrc->vd_cnt);
    ddest->vd_hash = bswap_32 (dsrc->vd_hash);
    ddest->vd_aux = bswap_32 (dsrc->vd_aux);
    ddest->vd_next = bswap_32 (dsrc->vd_next);
  }
      else
  {
    if (ddest->vd_next > len - def_offset)
      return;
    def_offset += ddest->vd_next;
  }
    }
  while (dsrc->vd_next != 0);
}


static void
elf_cvt_Verneed (void *dest, const void *src, size_t len, int encode)
{
  /* We have two different record types: ElfXX_Verndef and ElfXX_Verdaux.
     To recognize them we have to walk the data structure and convert
     them one after the other.  The ENCODE parameter specifies whether
     we are encoding or decoding.  When we are encoding we can immediately
     use the data in the buffer; if not, we have to decode the data before
     using it.  */
  size_t need_offset = 0;
  GElf_Verneed *ndest;
  GElf_Verneed *nsrc;

  /* We rely on the types being all the same size.  */
  assert (sizeof (GElf_Verneed) == sizeof (Elf32_Verneed));
  assert (sizeof (GElf_Vernaux) == sizeof (Elf32_Vernaux));
  assert (sizeof (GElf_Verneed) == sizeof (Elf64_Verneed));
  assert (sizeof (GElf_Vernaux) == sizeof (Elf64_Vernaux));

  if (len == 0)
    return;

  /* Below we rely on the next field offsets to be correct, start by
     copying over all data as is in case some data isn't translated.
     We don't want to leave (undefined) garbage in the dest buffer.  */
  memmove (dest, src, len);

  do
    {
      size_t aux_offset;
      GElf_Vernaux *asrc;

      /* Test for correct offset.  */
      if (need_offset > len
    || len - need_offset < sizeof (GElf_Verneed)
    || (need_offset & (__alignof__ (GElf_Verneed) - 1)) != 0)
  return;

      /* Work the tree from the first record.  */
      ndest = (GElf_Verneed *) ((char *) dest + need_offset);
      nsrc = (GElf_Verneed *) ((char *) src + need_offset);

      /* Decode first if necessary.  */
      if (! encode)
  {
    ndest->vn_version = bswap_16 (nsrc->vn_version);
    ndest->vn_cnt = bswap_16 (nsrc->vn_cnt);
    ndest->vn_file = bswap_32 (nsrc->vn_file);
    ndest->vn_aux = bswap_32 (nsrc->vn_aux);
    ndest->vn_next = bswap_32 (nsrc->vn_next);

    if (ndest->vn_aux > len - need_offset)
      return;
    aux_offset = need_offset + ndest->vn_aux;
  }
      else
  {
    if (nsrc->vn_aux > len - need_offset)
      return;
    aux_offset = need_offset + nsrc->vn_aux;
  }

      /* Handle all the auxiliary records belonging to this requirement.  */
      do
  {
    GElf_Vernaux *adest;

    /* Test for correct offset.  */
    if (aux_offset > len
        || len - aux_offset < sizeof (GElf_Vernaux)
        || (aux_offset & (__alignof__ (GElf_Vernaux) - 1)) != 0)
      return;

    adest = (GElf_Vernaux *) ((char *) dest + aux_offset);
    asrc = (GElf_Vernaux *) ((char *) src + aux_offset);

    if (encode)
      {
        if (asrc->vna_next > len - aux_offset)
    return;
        aux_offset += asrc->vna_next;
      }

    adest->vna_hash = bswap_32 (asrc->vna_hash);
    adest->vna_flags = bswap_16 (asrc->vna_flags);
    adest->vna_other = bswap_16 (asrc->vna_other);
    adest->vna_name = bswap_32 (asrc->vna_name);
    adest->vna_next = bswap_32 (asrc->vna_next);

    if (! encode)
      {
        if (adest->vna_next > len - aux_offset)
    return;
        aux_offset += adest->vna_next;
      }
  }
      while (asrc->vna_next != 0);

      /* Encode now if necessary.  */
      if (encode)
  {
    if (nsrc->vn_next > len - need_offset)
      return;
    need_offset += nsrc->vn_next;

    ndest->vn_version = bswap_16 (nsrc->vn_version);
    ndest->vn_cnt = bswap_16 (nsrc->vn_cnt);
    ndest->vn_file = bswap_32 (nsrc->vn_file);
    ndest->vn_aux = bswap_32 (nsrc->vn_aux);
    ndest->vn_next = bswap_32 (nsrc->vn_next);
  }
      else
  {
    if (ndest->vn_next > len - need_offset)
      return;
    need_offset += ndest->vn_next;
  }
    }
  while (nsrc->vn_next != 0);
}

Coverage Report

Created: 2026-01-09 07:05

Line	Count	Source
1		/* Conversion functions for versioning information.
2		Copyright (C) 1998, 1999, 2000, 2002, 2003, 2015 Red Hat, Inc.
3		Copyright (C) 2022 Mark J. Wielaard <mark@klomp.org>
4		This file is part of elfutils.
5		Written by Ulrich Drepper <drepper@redhat.com>, 1998.
6
7		This file is free software; you can redistribute it and/or modify
8		it under the terms of either
9
10		* the GNU Lesser General Public License as published by the Free
11		Software Foundation; either version 3 of the License, or (at
12		your option) any later version
13
14		or
15
16		* the GNU General Public License as published by the Free
17		Software Foundation; either version 2 of the License, or (at
18		your option) any later version
19
20		or both in parallel, as here.
21
22		elfutils is distributed in the hope that it will be useful, but
23		WITHOUT ANY WARRANTY; without even the implied warranty of
24		MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
25		General Public License for more details.
26
27		You should have received copies of the GNU General Public License and
28		the GNU Lesser General Public License along with this program. If
29		not, see <http://www.gnu.org/licenses/>. */
30
31		#include <assert.h>
32		#include <gelf.h>
33
34		#include "libelfP.h"
35
36
37		static void
38		elf_cvt_Verdef (void dest, const void src, size_t len, int encode)
39	712	{
40		/* We have two different record types: ElfXX_Verndef and ElfXX_Verdaux.
41		To recognize them we have to walk the data structure and convert
42		them one after the other. The ENCODE parameter specifies whether
43		we are encoding or decoding. When we are encoding we can immediately
44		use the data in the buffer; if not, we have to decode the data before
45		using it. */
46	712	size_t def_offset = 0;
47	712	GElf_Verdef *ddest;
48	712	GElf_Verdef *dsrc;
49
50		/* We rely on the types being all the same size. */
51	712	assert (sizeof (GElf_Verdef) == sizeof (Elf32_Verdef));
52	712	assert (sizeof (GElf_Verdaux) == sizeof (Elf32_Verdaux));
53	712	assert (sizeof (GElf_Verdef) == sizeof (Elf64_Verdef));
54	712	assert (sizeof (GElf_Verdaux) == sizeof (Elf64_Verdaux));
55
56	712	if (len == 0)
57	0	return;
58
59		/* Below we rely on the next field offsets to be correct, start by
60		copying over all data as is in case some data isn't translated.
61		We don't want to leave (undefined) garbage in the dest buffer. */
62	712	memmove (dest, src, len);
63
64	712	do
65	1.07k	{
66	1.07k	size_t aux_offset;
67	1.07k	GElf_Verdaux *asrc;
68
69		/* Test for correct offset. */
70	1.07k	if (def_offset > len
71	1.07k	\|\| len - def_offset < sizeof (GElf_Verdef)
72	1.03k	\|\| (def_offset & (__alignof__ (GElf_Verdef) - 1)) != 0)
73	66	return;
74
75		/* Work the tree from the first record. */
76	1.01k	ddest = (GElf_Verdef ) ((char ) dest + def_offset);
77	1.01k	dsrc = (GElf_Verdef ) ((char ) src + def_offset);
78
79		/* Decode first if necessary. */
80	1.01k	if (! encode)
81	1.01k	{
82	1.01k	ddest->vd_version = bswap_16 (dsrc->vd_version);
83	1.01k	ddest->vd_flags = bswap_16 (dsrc->vd_flags);
84	1.01k	ddest->vd_ndx = bswap_16 (dsrc->vd_ndx);
85	1.01k	ddest->vd_cnt = bswap_16 (dsrc->vd_cnt);
86	1.01k	ddest->vd_hash = bswap_32 (dsrc->vd_hash);
87	1.01k	ddest->vd_aux = bswap_32 (dsrc->vd_aux);
88	1.01k	ddest->vd_next = bswap_32 (dsrc->vd_next);
89
90	1.01k	if (ddest->vd_aux > len - def_offset)
91	250	return;
92	762	aux_offset = def_offset + ddest->vd_aux;
93	762	}
94	0	else
95	0	{
96	0	if (dsrc->vd_aux > len - def_offset)
97	0	return;
98	0	aux_offset = def_offset + dsrc->vd_aux;
99	0	}
100
101		/* Handle all the auxiliary records belonging to this definition. */
102	762	do
103	5.01k	{
104	5.01k	GElf_Verdaux *adest;
105
106		/* Test for correct offset. */
107	5.01k	if (aux_offset > len
108	5.01k	\|\| len - aux_offset < sizeof (GElf_Verdaux)
109	4.95k	\|\| (aux_offset & (__alignof__ (GElf_Verdaux) - 1)) != 0)
110	129	return;
111
112	4.88k	adest = (GElf_Verdaux ) ((char ) dest + aux_offset);
113	4.88k	asrc = (GElf_Verdaux ) ((char ) src + aux_offset);
114
115	4.88k	if (encode)
116	0	{
117	0	if (asrc->vda_next > len - aux_offset)
118	0	return;
119	0	aux_offset += asrc->vda_next;
120	0	}
121
122	4.88k	adest->vda_name = bswap_32 (asrc->vda_name);
123	4.88k	adest->vda_next = bswap_32 (asrc->vda_next);
124
125	4.88k	if (! encode)
126	4.88k	{
127	4.88k	if (adest->vda_next > len - aux_offset)
128	83	return;
129	4.80k	aux_offset += adest->vda_next;
130	4.80k	}
131	4.88k	}
132	4.80k	while (asrc->vda_next != 0);
133
134		/* Encode now if necessary. */
135	550	if (encode)
136	0	{
137	0	if (dsrc->vd_next > len - def_offset)
138	0	return;
139	0	def_offset += dsrc->vd_next;
140
141	0	ddest->vd_version = bswap_16 (dsrc->vd_version);
142	0	ddest->vd_flags = bswap_16 (dsrc->vd_flags);
143	0	ddest->vd_ndx = bswap_16 (dsrc->vd_ndx);
144	0	ddest->vd_cnt = bswap_16 (dsrc->vd_cnt);
145	0	ddest->vd_hash = bswap_32 (dsrc->vd_hash);
146	0	ddest->vd_aux = bswap_32 (dsrc->vd_aux);
147	0	ddest->vd_next = bswap_32 (dsrc->vd_next);
148	0	}
149	550	else
150	550	{
151	550	if (ddest->vd_next > len - def_offset)
152	73	return;
153	477	def_offset += ddest->vd_next;
154	477	}
155	550	}
156	712	while (dsrc->vd_next != 0);
157	712	}
158
159
160		static void
161		elf_cvt_Verneed (void dest, const void src, size_t len, int encode)
162	1.15k	{
163		/* We have two different record types: ElfXX_Verndef and ElfXX_Verdaux.
164		To recognize them we have to walk the data structure and convert
165		them one after the other. The ENCODE parameter specifies whether
166		we are encoding or decoding. When we are encoding we can immediately
167		use the data in the buffer; if not, we have to decode the data before
168		using it. */
169	1.15k	size_t need_offset = 0;
170	1.15k	GElf_Verneed *ndest;
171	1.15k	GElf_Verneed *nsrc;
172
173		/* We rely on the types being all the same size. */
174	1.15k	assert (sizeof (GElf_Verneed) == sizeof (Elf32_Verneed));
175	1.15k	assert (sizeof (GElf_Vernaux) == sizeof (Elf32_Vernaux));
176	1.15k	assert (sizeof (GElf_Verneed) == sizeof (Elf64_Verneed));
177	1.15k	assert (sizeof (GElf_Vernaux) == sizeof (Elf64_Vernaux));
178
179	1.15k	if (len == 0)
180	0	return;
181
182		/* Below we rely on the next field offsets to be correct, start by
183		copying over all data as is in case some data isn't translated.
184		We don't want to leave (undefined) garbage in the dest buffer. */
185	1.15k	memmove (dest, src, len);
186
187	1.15k	do
188	1.71k	{
189	1.71k	size_t aux_offset;
190	1.71k	GElf_Vernaux *asrc;
191
192		/* Test for correct offset. */
193	1.71k	if (need_offset > len
194	1.71k	\|\| len - need_offset < sizeof (GElf_Verneed)
195	1.61k	\|\| (need_offset & (__alignof__ (GElf_Verneed) - 1)) != 0)
196	177	return;
197
198		/* Work the tree from the first record. */
199	1.54k	ndest = (GElf_Verneed ) ((char ) dest + need_offset);
200	1.54k	nsrc = (GElf_Verneed ) ((char ) src + need_offset);
201
202		/* Decode first if necessary. */
203	1.54k	if (! encode)
204	1.54k	{
205	1.54k	ndest->vn_version = bswap_16 (nsrc->vn_version);
206	1.54k	ndest->vn_cnt = bswap_16 (nsrc->vn_cnt);
207	1.54k	ndest->vn_file = bswap_32 (nsrc->vn_file);
208	1.54k	ndest->vn_aux = bswap_32 (nsrc->vn_aux);
209	1.54k	ndest->vn_next = bswap_32 (nsrc->vn_next);
210
211	1.54k	if (ndest->vn_aux > len - need_offset)
212	228	return;
213	1.31k	aux_offset = need_offset + ndest->vn_aux;
214	1.31k	}
215	0	else
216	0	{
217	0	if (nsrc->vn_aux > len - need_offset)
218	0	return;
219	0	aux_offset = need_offset + nsrc->vn_aux;
220	0	}
221
222		/* Handle all the auxiliary records belonging to this requirement. */
223	1.31k	do
224	9.46k	{
225	9.46k	GElf_Vernaux *adest;
226
227		/* Test for correct offset. */
228	9.46k	if (aux_offset > len
229	9.46k	\|\| len - aux_offset < sizeof (GElf_Vernaux)
230	9.37k	\|\| (aux_offset & (__alignof__ (GElf_Vernaux) - 1)) != 0)
231	256	return;
232
233	9.21k	adest = (GElf_Vernaux ) ((char ) dest + aux_offset);
234	9.21k	asrc = (GElf_Vernaux ) ((char ) src + aux_offset);
235
236	9.21k	if (encode)
237	0	{
238	0	if (asrc->vna_next > len - aux_offset)
239	0	return;
240	0	aux_offset += asrc->vna_next;
241	0	}
242
243	9.21k	adest->vna_hash = bswap_32 (asrc->vna_hash);
244	9.21k	adest->vna_flags = bswap_16 (asrc->vna_flags);
245	9.21k	adest->vna_other = bswap_16 (asrc->vna_other);
246	9.21k	adest->vna_name = bswap_32 (asrc->vna_name);
247	9.21k	adest->vna_next = bswap_32 (asrc->vna_next);
248
249	9.21k	if (! encode)
250	9.21k	{
251	9.21k	if (adest->vna_next > len - aux_offset)
252	189	return;
253	9.02k	aux_offset += adest->vna_next;
254	9.02k	}
255	9.21k	}
256	9.02k	while (asrc->vna_next != 0);
257
258		/* Encode now if necessary. */
259	869	if (encode)
260	0	{
261	0	if (nsrc->vn_next > len - need_offset)
262	0	return;
263	0	need_offset += nsrc->vn_next;
264
265	0	ndest->vn_version = bswap_16 (nsrc->vn_version);
266	0	ndest->vn_cnt = bswap_16 (nsrc->vn_cnt);
267	0	ndest->vn_file = bswap_32 (nsrc->vn_file);
268	0	ndest->vn_aux = bswap_32 (nsrc->vn_aux);
269	0	ndest->vn_next = bswap_32 (nsrc->vn_next);
270	0	}
271	869	else
272	869	{
273	869	if (ndest->vn_next > len - need_offset)
274	121	return;
275	748	need_offset += ndest->vn_next;
276	748	}
277	869	}
278	1.15k	while (nsrc->vn_next != 0);
279	1.15k	}