/* Return the next data element from the section after possibly converting it.
Copyright (C) 1998-2005, 2006, 2007, 2015, 2016 Red Hat, Inc.
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/>. */
#ifdef HAVE_CONFIG_H
# include <config.h>
#endif
#include <errno.h>
#include <stddef.h>
#include <string.h>
#include <unistd.h>
#include "libelfP.h"
#include <system.h>
#include "common.h"
#include "elf-knowledge.h"
#define TYPEIDX(Sh_Type) \
(Sh_Type >= SHT_NULL && Sh_Type < SHT_NUM \
? Sh_Type \
: (Sh_Type >= SHT_GNU_HASH && Sh_Type <= SHT_HISUNW \
? SHT_NUM + Sh_Type - SHT_GNU_HASH \
: 0))
/* Associate section types with libelf types. */
static const Elf_Type shtype_map[TYPEIDX (SHT_HISUNW) + 1] =
{
[SHT_SYMTAB] = ELF_T_SYM,
[SHT_RELA] = ELF_T_RELA,
[SHT_HASH] = ELF_T_WORD,
[SHT_DYNAMIC] = ELF_T_DYN,
[SHT_REL] = ELF_T_REL,
[SHT_DYNSYM] = ELF_T_SYM,
[SHT_INIT_ARRAY] = ELF_T_ADDR,
[SHT_FINI_ARRAY] = ELF_T_ADDR,
[SHT_PREINIT_ARRAY] = ELF_T_ADDR,
[SHT_GROUP] = ELF_T_WORD,
[SHT_SYMTAB_SHNDX] = ELF_T_WORD,
[SHT_NOTE] = ELF_T_NHDR, /* Need alignment to guess ELF_T_NHDR8. */
[TYPEIDX (SHT_GNU_verdef)] = ELF_T_VDEF,
[TYPEIDX (SHT_GNU_verneed)] = ELF_T_VNEED,
[TYPEIDX (SHT_GNU_versym)] = ELF_T_HALF,
[TYPEIDX (SHT_SUNW_syminfo)] = ELF_T_SYMINFO,
[TYPEIDX (SHT_SUNW_move)] = ELF_T_MOVE,
[TYPEIDX (SHT_GNU_LIBLIST)] = ELF_T_LIB,
[TYPEIDX (SHT_GNU_HASH)] = ELF_T_GNUHASH,
};
/* Associate libelf types with their internal alignment requirements. */
const uint_fast8_t __libelf_type_aligns[ELFCLASSNUM - 1][ELF_T_NUM] =
{
# define TYPE_ALIGNS(Bits) \
{ \
[ELF_T_ADDR] = __alignof__ (ElfW2(Bits,Addr)), \
[ELF_T_EHDR] = __alignof__ (ElfW2(Bits,Ehdr)), \
[ELF_T_HALF] = __alignof__ (ElfW2(Bits,Half)), \
[ELF_T_OFF] = __alignof__ (ElfW2(Bits,Off)), \
[ELF_T_PHDR] = __alignof__ (ElfW2(Bits,Phdr)), \
[ELF_T_SHDR] = __alignof__ (ElfW2(Bits,Shdr)), \
[ELF_T_SWORD] = __alignof__ (ElfW2(Bits,Sword)), \
[ELF_T_WORD] = __alignof__ (ElfW2(Bits,Word)), \
[ELF_T_XWORD] = __alignof__ (ElfW2(Bits,Xword)), \
[ELF_T_SXWORD] = __alignof__ (ElfW2(Bits,Sxword)), \
[ELF_T_SYM] = __alignof__ (ElfW2(Bits,Sym)), \
[ELF_T_SYMINFO] = __alignof__ (ElfW2(Bits,Syminfo)), \
[ELF_T_REL] = __alignof__ (ElfW2(Bits,Rel)), \
[ELF_T_RELA] = __alignof__ (ElfW2(Bits,Rela)), \
[ELF_T_DYN] = __alignof__ (ElfW2(Bits,Dyn)), \
[ELF_T_VDEF] = __alignof__ (ElfW2(Bits,Verdef)), \
[ELF_T_VDAUX] = __alignof__ (ElfW2(Bits,Verdaux)), \
[ELF_T_VNEED] = __alignof__ (ElfW2(Bits,Verneed)), \
[ELF_T_VNAUX] = __alignof__ (ElfW2(Bits,Vernaux)), \
[ELF_T_MOVE] = __alignof__ (ElfW2(Bits,Move)), \
[ELF_T_LIB] = __alignof__ (ElfW2(Bits,Lib)), \
[ELF_T_NHDR] = __alignof__ (ElfW2(Bits,Nhdr)), \
[ELF_T_GNUHASH] = __alignof__ (Elf32_Word), \
[ELF_T_AUXV] = __alignof__ (ElfW2(Bits,auxv_t)), \
[ELF_T_CHDR] = __alignof__ (ElfW2(Bits,Chdr)), \
[ELF_T_NHDR8] = 8 /* Special case for GNU Property note. */ \
}
[ELFCLASS32 - 1] = TYPE_ALIGNS (32),
[ELFCLASS64 - 1] = TYPE_ALIGNS (64),
# undef TYPE_ALIGNS
};
Elf_Type
internal_function
__libelf_data_type (Elf *elf, int sh_type, GElf_Xword align)
{
/* Some broken ELF ABI for 64-bit machines use the wrong hash table
entry size. See elf-knowledge.h for more information. */
if (sh_type == SHT_HASH && elf->class == ELFCLASS64)
{
GElf_Ehdr ehdr_mem;
GElf_Ehdr *ehdr = __gelf_getehdr_rdlock (elf, &ehdr_mem);
return (SH_ENTSIZE_HASH (ehdr) == 4 ? ELF_T_WORD : ELF_T_XWORD);
}
else
{
Elf_Type t = shtype_map[TYPEIDX (sh_type)];
/* Special case for GNU Property notes. */
if (t == ELF_T_NHDR && align == 8)
t = ELF_T_NHDR8;
return t;
}
}
/* Convert the data in the current section. */
static void
convert_data (Elf_Scn *scn, int eclass,
int data, size_t size, Elf_Type type)
{
const size_t align = __libelf_type_align (eclass, type);
/* Do we need to convert the data and/or adjust for alignment? */
if (data == MY_ELFDATA || type == ELF_T_BYTE)
{
if (((((size_t) (char *) scn->rawdata_base)) & (align - 1)) == 0)
/* No need to copy, we can use the raw data. */
scn->data_base = scn->rawdata_base;
else
{
scn->data_base = (char *) malloc (size);
if (scn->data_base == NULL)
{
__libelf_seterrno (ELF_E_NOMEM);
return;
}
/* The copy will be appropriately aligned for direct access. */
memcpy (scn->data_base, scn->rawdata_base, size);
}
}
else
{
xfct_t fp;
scn->data_base = (char *) malloc (size);
if (scn->data_base == NULL)
{
__libelf_seterrno (ELF_E_NOMEM);
return;
}
/* Make sure the source is correctly aligned for the conversion
function to directly access the data elements. */
char *rawdata_source;
if (((((size_t) (char *) scn->rawdata_base)) & (align - 1)) == 0)
rawdata_source = scn->rawdata_base;
else
{
rawdata_source = (char *) malloc (size);
if (rawdata_source == NULL)
{
__libelf_seterrno (ELF_E_NOMEM);
return;
}
/* The copy will be appropriately aligned for direct access. */
memcpy (rawdata_source, scn->rawdata_base, size);
}
/* Get the conversion function. */
fp = __elf_xfctstom[eclass - 1][type];
fp (scn->data_base, rawdata_source, size, 0);
if (rawdata_source != scn->rawdata_base)
free (rawdata_source);
}
scn->data_list.data.d.d_buf = scn->data_base;
scn->data_list.data.d.d_size = size;
scn->data_list.data.d.d_type = type;
scn->data_list.data.d.d_off = scn->rawdata.d.d_off;
scn->data_list.data.d.d_align = scn->rawdata.d.d_align;
scn->data_list.data.d.d_version = scn->rawdata.d.d_version;
scn->data_list.data.s = scn;
}
/* Store the information for the raw data in the `rawdata' element. */
int
internal_function
__libelf_set_rawdata_wrlock (Elf_Scn *scn)
{
Elf64_Off offset;
Elf64_Xword size;
Elf64_Xword align;
Elf64_Xword flags;
int type;
Elf *elf = scn->elf;
if (elf->class == ELFCLASS32)
{
Elf32_Shdr *shdr
= scn->shdr.e32 ?: __elf32_getshdr_wrlock (scn);
if (shdr == NULL)
/* Something went terribly wrong. */
return 1;
offset = shdr->sh_offset;
size = shdr->sh_size;
type = shdr->sh_type;
align = shdr->sh_addralign;
flags = shdr->sh_flags;
}
else
{
Elf64_Shdr *shdr
= scn->shdr.e64 ?: __elf64_getshdr_wrlock (scn);
if (shdr == NULL)
/* Something went terribly wrong. */
return 1;
offset = shdr->sh_offset;
size = shdr->sh_size;
type = shdr->sh_type;
align = shdr->sh_addralign;
flags = shdr->sh_flags;
}
/* If the section has no data (for whatever reason), leave the `d_buf'
pointer NULL. */
if (size != 0 && type != SHT_NOBITS)
{
/* First a test whether the section is valid at all. */
size_t entsize;
/* Compressed data has a header, but then compressed data.
Make sure to set the alignment of the header explicitly,
don't trust the file alignment for the section, it is
often wrong. */
if ((flags & SHF_COMPRESSED) != 0)
{
entsize = 1;
align = __libelf_type_align (elf->class, ELF_T_CHDR);
}
else if (type == SHT_HASH)
{
GElf_Ehdr ehdr_mem;
GElf_Ehdr *ehdr = __gelf_getehdr_rdlock (elf, &ehdr_mem);
if (unlikely (ehdr == NULL))
return 1;
entsize = SH_ENTSIZE_HASH (ehdr);
}
else
{
Elf_Type t = shtype_map[TYPEIDX (type)];
if (t == ELF_T_NHDR && align == 8)
t = ELF_T_NHDR8;
if (t == ELF_T_VDEF || t == ELF_T_NHDR || t == ELF_T_NHDR8
|| (t == ELF_T_GNUHASH && elf->class == ELFCLASS64))
entsize = 1;
else
entsize = __libelf_type_sizes[elf->class - 1][t];
}
/* We assume it is an array of bytes if it is none of the structured
sections we know of. */
if (entsize == 0)
entsize = 1;
if (unlikely (size % entsize != 0))
{
__libelf_seterrno (ELF_E_INVALID_DATA);
return 1;
}
/* We can use the mapped or loaded data if available. */
if (elf->map_address != NULL)
{
/* First see whether the information in the section header is
valid and it does not ask for too much. Check for unsigned
overflow. */
if (unlikely (offset > elf->maximum_size
|| elf->maximum_size - offset < size))
{
/* Something is wrong. */
__libelf_seterrno (ELF_E_INVALID_SECTION_HEADER);
return 1;
}
scn->rawdata_base = scn->rawdata.d.d_buf
= (char *) elf->map_address + elf->start_offset + offset;
}
else if (likely (elf->fildes != -1))
{
/* First see whether the information in the section header is
valid and it does not ask for too much. Check for unsigned
overflow. */
if (unlikely (offset > elf->maximum_size
|| elf->maximum_size - offset < size))
{
/* Something is wrong. */
__libelf_seterrno (ELF_E_INVALID_SECTION_HEADER);
return 1;
}
/* We have to read the data from the file. Allocate the needed
memory. */
scn->rawdata_base = scn->rawdata.d.d_buf
= (char *) malloc (size);
if (scn->rawdata.d.d_buf == NULL)
{
__libelf_seterrno (ELF_E_NOMEM);
return 1;
}
ssize_t n = pread_retry (elf->fildes, scn->rawdata.d.d_buf, size,
elf->start_offset + offset);
if (unlikely ((size_t) n != size))
{
/* Cannot read the data. */
free (scn->rawdata.d.d_buf);
scn->rawdata_base = scn->rawdata.d.d_buf = NULL;
__libelf_seterrno (ELF_E_READ_ERROR);
return 1;
}
}
else
{
/* The file descriptor is already closed, we cannot get the data
anymore. */
__libelf_seterrno (ELF_E_FD_DISABLED);
return 1;
}
}
scn->rawdata.d.d_size = size;
/* Compressed data always has type ELF_T_CHDR regardless of the
section type. */
if ((flags & SHF_COMPRESSED) != 0)
scn->rawdata.d.d_type = ELF_T_CHDR;
else
scn->rawdata.d.d_type = __libelf_data_type (elf, type, align);
scn->rawdata.d.d_off = 0;
/* Make sure the alignment makes sense. d_align should be aligned both
in the section (trivially true since d_off is zero) and in the file.
Unfortunately we cannot be too strict because there are ELF files
out there that fail this requirement. We will try to fix those up
in elf_update when writing out the image. But for very large
alignment values this can bloat the image considerably. So here
just check and clamp the alignment value to not be bigger than the
actual offset of the data in the file. Given that there is always
at least an ehdr this will only trigger for alignment values > 64
which should be uncommon. */
align = align ?: 1;
if (type != SHT_NOBITS && align > offset)
align = offset;
scn->rawdata.d.d_align = align;
if (elf->class == ELFCLASS32
|| (offsetof (struct Elf, state.elf32.ehdr)
== offsetof (struct Elf, state.elf64.ehdr)))
scn->rawdata.d.d_version =
elf->state.elf32.ehdr->e_ident[EI_VERSION];
else
scn->rawdata.d.d_version =
elf->state.elf64.ehdr->e_ident[EI_VERSION];
scn->rawdata.s = scn;
scn->data_read = 1;
/* We actually read data from the file. At least we tried. */
scn->flags |= ELF_F_FILEDATA;
return 0;
}
int
internal_function
__libelf_set_rawdata (Elf_Scn *scn)
{
int result;
if (scn == NULL)
return 1;
rwlock_wrlock (scn->elf->lock);
result = __libelf_set_rawdata_wrlock (scn);
rwlock_unlock (scn->elf->lock);
return result;
}
void
internal_function
__libelf_set_data_list_rdlock (Elf_Scn *scn, int wrlocked)
{
if (scn->rawdata.d.d_buf != NULL && scn->rawdata.d.d_size > 0)
{
Elf *elf = scn->elf;
/* Upgrade the lock to a write lock if necessary and check
nobody else already did the work. */
if (!wrlocked)
{
rwlock_unlock (elf->lock);
rwlock_wrlock (elf->lock);
if (scn->data_list_rear != NULL)
return;
}
/* Convert according to the version and the type. */
convert_data (scn, elf->class,
(elf->class == ELFCLASS32
|| (offsetof (struct Elf, state.elf32.ehdr)
== offsetof (struct Elf, state.elf64.ehdr))
? elf->state.elf32.ehdr->e_ident[EI_DATA]
: elf->state.elf64.ehdr->e_ident[EI_DATA]),
scn->rawdata.d.d_size, scn->rawdata.d.d_type);
}
else
{
/* This is an empty or NOBITS section. There is no buffer but
the size information etc is important. */
scn->data_list.data.d = scn->rawdata.d;
scn->data_list.data.s = scn;
}
scn->data_list_rear = &scn->data_list;
}
Elf_Data *
internal_function
__elf_getdata_rdlock (Elf_Scn *scn, Elf_Data *data)
{
Elf_Data *result = NULL;
Elf *elf;
int locked = 0;
if (scn == NULL)
return NULL;
if (unlikely (scn->elf->kind != ELF_K_ELF))
{
__libelf_seterrno (ELF_E_INVALID_HANDLE);
return NULL;
}
/* We will need this multiple times later on. */
elf = scn->elf;
/* If `data' is not NULL this means we are not addressing the initial
data in the file. But this also means this data is already read
(since otherwise it is not possible to have a valid `data' pointer)
and all the data structures are initialized as well. In this case
we can simply walk the list of data records. */
if (data != NULL)
{
Elf_Data_List *runp;
/* It is not possible that if DATA is not NULL the first entry is
returned. But this also means that there must be a first data
entry. */
if (scn->data_list_rear == NULL
/* The section the reference data is for must match the section
parameter. */
|| unlikely (((Elf_Data_Scn *) data)->s != scn))
{
__libelf_seterrno (ELF_E_DATA_MISMATCH);
goto out;
}
/* We start searching with the first entry. */
runp = &scn->data_list;
while (1)
{
/* If `data' does not match any known record punt. */
if (runp == NULL)
{
__libelf_seterrno (ELF_E_DATA_MISMATCH);
goto out;
}
if (&runp->data.d == data)
/* Found the entry. */
break;
runp = runp->next;
}
/* Return the data for the next data record. */
result = runp->next ? &runp->next->data.d : NULL;
goto out;
}
/* If the data for this section was not yet initialized do it now. */
if (scn->data_read == 0)
{
/* We cannot acquire a write lock while we are holding a read
lock. Therefore give up the read lock and then get the write
lock. But this means that the data could meanwhile be
modified, therefore start the tests again. */
rwlock_unlock (elf->lock);
rwlock_wrlock (elf->lock);
locked = 1;
/* Read the data from the file. There is always a file (or
memory region) associated with this descriptor since
otherwise the `data_read' flag would be set. */
if (scn->data_read == 0 && __libelf_set_rawdata_wrlock (scn) != 0)
/* Something went wrong. The error value is already set. */
goto out;
}
/* At this point we know the raw data is available. But it might be
empty in case the section has size zero (for whatever reason).
Now create the converted data in case this is necessary. */
if (scn->data_list_rear == NULL)
__libelf_set_data_list_rdlock (scn, locked);
/* Return the first data element in the list. */
result = &scn->data_list.data.d;
out:
return result;
}
Elf_Data *
elf_getdata (Elf_Scn *scn, Elf_Data *data)
{
Elf_Data *result;
if (scn == NULL)
return NULL;
rwlock_rdlock (scn->elf->lock);
result = __elf_getdata_rdlock (scn, data);
rwlock_unlock (scn->elf->lock);
return result;
}
INTDEF(elf_getdata)