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b5d3790c6684a85552e0f57372a2b3b7fae0ed96
binutils-gdb/libctf/ctf-archive.c
Nick Alcock b5d3790c66 libctf: consecutive ctf_id_t assignment 
This change modifies type ID assignment in CTF so that it works like BTF:
rather than flipping the high bit on for types in child dicts, types ascend
directly from IDs in the parent to IDs in the child, without interruption
(so type 0x4 in the parent is immediately followed by 0x5 in all children).

Doing this while retaining useful semantics for modification of parents is
challenging.  By definition, child type IDs are not known until the parent
is written out, but we don't want to find ourselves constrained to adding
types to the parent in one go, followed by all child types: that would make
the deduplicator a nightmare and would frankly make the entire ctf_add*()
interface next to useless: all existing clients that add types at all
add types to both parents and children without regard for ordering, and
breaking that would probably necessitate redesigning all of them.

So we have to be a litle cleverer.

We approach this the same way as we approach strings in the recent refs
rework: if a parent has children attached (or has ever had them attached
since it was created or last read in), any new types created in the parent
are assigned provisional IDs starting at the very top of the type space and
working down.  (Their indexes in the internal libctf arrays remain
unchanged, so we don't suddenly need multigigabyte indexes!).  At writeout
(preserialization) time, we traverse the type table (and all other table
containing type IDs) and assign refs to every type ID in exactly the same
way we assign refs to every string offset (just a different set of refs --
we don't want to update type IDs with string offset values!).

For a parent dict with children, these refs are real entities in memory:
pointers to the memory locations where type IDs are stored, tracked in the
DTD of each type.  As we traverse the type table, we assign real IDs to each
type (by simple incrementation), storing those IDs in a new dtd_final_type
field in the DTD for each type.  Once the type table and all other tables
containing type IDs are fully traversed, we update all the refs and
overwrite the IDs currently residing in each with the final IDs for each
type.

That fixes up IDs in the parent dict itself (including forward references in
structs and the like: that's why the ref updates only happen at the end);
but what about child dicts' references, both to parent types and to their
own?  We add armouring to enforce that parent dicts are always serialized
before their children (which ctf-link.c already does, because it's a
precondition for strtab deduplication), and then arrange that when a ref is
added to a type whose ID has been assigned (has a dtd_final_type), we just
immediately do an update rather than storing a ref for later updating.
Since the parent is already serialized, all parent type IDs have a
dtd_final_type by this point, and all parent IDs in the children are
properly updated. The child types can now be renumbered now we now the
number of types in the parent, and their refs updated identically to what
was just done with the parent.

One wrinkle: before the child refs are updated, while we are working over
the child's type section, the type IDs in the child start from 1 (or
something like that), which might seem to overlap the parent IDs.  But this
is not the case: when you serialize the parent, the IDs written out to disk
are changed, but the only change to the representation in memory is that we
remember a dtd_final_type for each type (and use it to update all the child
type refs): its ID in memory is the same as it always was, a nonoverlapping
provisional ID higher than any other valid ID.  We enforce all of this by
asserting that when you add a ref to a type, the memory location that is
modified must be in the buffer being serialized: the code will not let you
accidentally modify the actual DTDs in memory.

We track the number of types in the parent in a new CTFv4 (not BTF) header
field (the dumper is updated): we will also use this to open CTFv3 child
dicts without change by simply declaring for them that the parent dict has
2^31 types in it (or 2^15, for v2 and below): the IDs in the children then
naturally come out right with no other changes needed.  (Right now, opening
CTFv3 child dicts requires extra compatibility code that has not been
written, but that code will no longer need to worry about type ID
differences.)

Various things are newly forbidden:

 - you cannot ctf_import() a child into a parent if you already ctf_add()ed
   types to the child, because all its IDs would change (and since you
   already cannot ctf_add() types to a child that hasn't had its parent
   imported, this in practice means only that ctf_create() must be followed
   immediately by a ctf_import() if this is a new child, which all sane
   clients were doing anyway).

 - You cannot import a child into a parent which has the wrong number of
   (non-provisional) types, again because all its IDs would be wrong:
   because parents only add types in the provisional space if children are
   attached to it, this would break the not unknown case of opening an
   archive, adding types to the parent, and only then importing children
   into it, so we add a special case: archive members which are not children
   in an archive with more than one member always pretend to have at least
   one child, so type additions in them are always provisional even before
   you ctf_import anything. In practice, this does exactly what we want,
   since all archives so far are created by the linker and have one parent
   and N children of that parent.

Because this introduces huge gaps between index and type ID for provisional
types, some extra assertions are added to ensure that the internal
ctf_type_to_index() is only ever called on types in the current dict (never
a parent dict): before now, this was just taken on trust, and it was often
wrong (which at best led to wrong results, as wrong array indexes were used,
and at worst to a buffer overflow). When hash debugging is on (suggesting
that the user doesn't mind expensive checks), every ctf_type_to_index()
triggers a ctf_index_to_type() to make sure that the operations are proper
inverses.

Lots and lots of tests are added to verify that assignment works and that
updating of every type kind works fine -- existing tests suffice for
type IDs in the variable and symtypetab sections.

The ld-ctf tests get a bunch of largely display-based updates: various
tests refer to 0x8... type IDs, which no longer exist, and because the
IDs are shorter all the spacing and alignment has changed.
2025-03-16 15:25:27 +00:00

1487 lines
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/* CTF archive files.
Copyright (C) 2019-2025 Free Software Foundation, Inc.
This file is part of libctf.
libctf is free software; you can redistribute it and/or modify it under
the terms of the GNU General Public License as published by the Free
Software Foundation; either version 3, or (at your option) any later
version.
This program 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 a copy of the GNU General Public License
along with this program; see the file COPYING. If not see
<http://www.gnu.org/licenses/>. */
#include <ctf-impl.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <elf.h>
#include "ctf-endian.h"
#include <errno.h>
#include <fcntl.h>
#include <stdio.h>
#include <string.h>
#include <unistd.h>
#ifdef HAVE_MMAP
#include <sys/mman.h>
#endif
static off_t arc_write_one_ctf (ctf_dict_t * f, int fd, size_t threshold);
static ctf_dict_t *ctf_dict_open_by_offset (const struct ctf_archive *arc,
const ctf_sect_t *symsect,
const ctf_sect_t *strsect,
size_t offset, int little_endian,
int *errp);
static int sort_modent_by_name (const void *one, const void *two, void *n);
static void *arc_mmap_header (int fd, size_t headersz);
static void *arc_mmap_file (int fd, size_t size);
static int arc_mmap_writeout (int fd, void *header, size_t headersz,
const char **errmsg);
static int arc_mmap_unmap (void *header, size_t headersz, const char **errmsg);
static int ctf_arc_import_parent (const ctf_archive_t *arc, ctf_dict_t *fp,
int *errp);
/* Flag to indicate "symbol not present" in ctf_archive_internal.ctfi_symdicts
and ctfi_symnamedicts. Never initialized. */
static ctf_dict_t enosym;
/* Prepare to serialize everything. Members of archives have dependencies on
each other, because the strtabs and type IDs of children depend on the
parent: so we have to work over the archive as a whole to prepare for final
serialization.
Returns zero on success, or an errno, or an ECTF_* value.
Updates the first dict in the archive with the errno value. */
static int
ctf_arc_preserialize (ctf_dict_t **ctf_dicts, ssize_t ctf_dict_cnt)
{
uint64_t old_parent_strlen, all_strlens = 0;
ssize_t i;
int err;
ctf_dprintf ("Preserializing dicts.\n");
/* Preserialize everything, doing everything but strtab generation and things
that depend on that. */
for (i = 0; i < ctf_dict_cnt; i++)
if (ctf_preserialize (ctf_dicts[i]) < 0)
goto err;
ctf_dprintf ("Deduplicating strings.\n");
for (i = 0; i < ctf_dict_cnt; i++)
all_strlens += ctf_dicts[i]->ctf_str[0].cts_len
+ ctf_dicts[i]->ctf_str_prov_len;
/* If linking, deduplicate strings against the children in every dict that has
any. (String deduplication is not yet implemented for non-linked dicts.) */
for (i = 0; i < ctf_dict_cnt; i++)
if (ctf_dicts[i]->ctf_flags & LCTF_LINKING && ctf_dicts[i]->ctf_link_outputs)
{
old_parent_strlen = ctf_dicts[i]->ctf_str[0].cts_len
+ ctf_dicts[i]->ctf_str_prov_len;
if (ctf_dedup_strings (ctf_dicts[i]) < 0)
goto err;
ctf_dprintf ("Deduplicated strings in archive member %zi: "
"original parent strlen: %zu; original lengths: %zu; "
"final length: %zu.\n", i, (size_t) old_parent_strlen,
(size_t) all_strlens,
(size_t) ctf_dicts[i]->ctf_str_prov_len);
}
return 0;
err:
err = ctf_errno (ctf_dicts[i]);
ctf_err_copy (ctf_dicts[0], ctf_dicts[i]);
for (i--; i >= 0; i--)
ctf_depreserialize (ctf_dicts[i]);
return err;
}
/* Write out a CTF archive to the start of the file referenced by the passed-in
fd. The entries in CTF_DICTS are referenced by name: the names are passed in
the names array, which must have CTF_DICTS entries.
Returns 0 on success, or an errno, or an ECTF_* value. */
int
ctf_arc_write_fd (int fd, ctf_dict_t **ctf_dicts, size_t ctf_dict_cnt,
const char **names, size_t threshold)
{
const char *errmsg;
struct ctf_archive *archdr;
size_t i;
char dummy = 0;
size_t headersz;
ssize_t namesz;
size_t ctf_startoffs; /* Start of the section we are working over. */
char *nametbl = NULL; /* The name table. */
char *np;
off_t nameoffs;
int err;
struct ctf_archive_modent *modent;
/* Prepare by serializing everything. Done first because it allocates a lot
of space and thus is more likely to fail. */
if (ctf_dict_cnt > 0 &&
(err = ctf_arc_preserialize (ctf_dicts, ctf_dict_cnt)) < 0)
return err;
ctf_dprintf ("Writing CTF archive with %lu files\n",
(unsigned long) ctf_dict_cnt);
/* Figure out the size of the mmap()ed header, including the
ctf_archive_modent array. We assume that all of this needs no
padding: a likely assumption, given that it's all made up of
uint64_t's. */
headersz = sizeof (struct ctf_archive)
+ (ctf_dict_cnt * sizeof (uint64_t) * 2);
ctf_dprintf ("headersz is %lu\n", (unsigned long) headersz);
/* From now on we work in two pieces: an mmap()ed region from zero up to the
headersz, and a region updated via write() starting after that, containing
all the tables. Platforms that do not support mmap() just use write(). */
ctf_startoffs = headersz;
if (lseek (fd, ctf_startoffs - 1, SEEK_SET) < 0)
{
errmsg = N_("ctf_arc_write(): cannot extend file while writing");
goto err;
}
if (write (fd, &dummy, 1) < 0)
{
errmsg = N_("ctf_arc_write(): cannot extend file while writing");
goto err;
}
if ((archdr = arc_mmap_header (fd, headersz)) == NULL)
{
errmsg = N_("ctf_arc_write(): cannot mmap");
goto err;
}
/* Fill in everything we can, which is everything other than the name
table offset. */
archdr->ctfa_magic = htole64 (CTFA_MAGIC);
archdr->ctfa_ndicts = htole64 (ctf_dict_cnt);
archdr->ctfa_ctfs = htole64 (ctf_startoffs);
/* We could validate that all CTF files have the same data model, but
since any reasonable construction process will be building things of
only one bitness anyway, this is pretty pointless, so just use the
model of the first CTF file for all of them. (It *is* valid to
create an empty archive: the value of ctfa_model is irrelevant in
this case, but we must be sure not to dereference uninitialized
memory.) */
if (ctf_dict_cnt > 0)
archdr->ctfa_model = htole64 (ctf_getmodel (ctf_dicts[0]));
/* Now write out the CTFs: ctf_archive_modent array via the mapping,
ctfs via write(). The names themselves have not been written yet: we
track them in a local strtab until the time is right, and sort the
modents array after construction.
The name table is not sorted. */
for (i = 0, namesz = 0; i < le64toh (archdr->ctfa_ndicts); i++)
namesz += strlen (names[i]) + 1;
nametbl = malloc (namesz);
if (nametbl == NULL)
{
errmsg = N_("ctf_arc_write(): error writing named CTF to archive");
goto err_unmap;
}
for (i = 0, namesz = 0,
modent = (ctf_archive_modent_t *) ((char *) archdr
+ sizeof (struct ctf_archive));
i < le64toh (archdr->ctfa_ndicts); i++)
{
off_t off;
strcpy (&nametbl[namesz], names[i]);
off = arc_write_one_ctf (ctf_dicts[i], fd, threshold);
if ((off < 0) && (off > -ECTF_BASE))
{
errmsg = N_("ctf_arc_write(): cannot determine file "
"position while writing to archive");
goto err_free;
}
if (off < 0)
{
errmsg = N_("ctf_arc_write(): cannot write CTF file to archive");
errno = off * -1;
goto err_free;
}
modent->name_offset = htole64 (namesz);
modent->ctf_offset = htole64 (off - ctf_startoffs);
namesz += strlen (names[i]) + 1;
modent++;
}
ctf_qsort_r ((ctf_archive_modent_t *) ((char *) archdr
+ sizeof (struct ctf_archive)),
le64toh (archdr->ctfa_ndicts),
sizeof (struct ctf_archive_modent), sort_modent_by_name,
nametbl);
/* Now the name table. */
if ((nameoffs = lseek (fd, 0, SEEK_CUR)) < 0)
{
errmsg = N_("ctf_arc_write(): cannot get current file position "
"in archive");
goto err_free;
}
archdr->ctfa_names = htole64 (nameoffs);
np = nametbl;
while (namesz > 0)
{
ssize_t len;
if ((len = write (fd, np, namesz)) < 0)
{
errmsg = N_("ctf_arc_write(): cannot write name table to archive");
goto err_free;
}
namesz -= len;
np += len;
}
free (nametbl);
if (arc_mmap_writeout (fd, archdr, headersz, &errmsg) < 0)
goto err_unmap;
if (arc_mmap_unmap (archdr, headersz, &errmsg) < 0)
goto err;
return 0;
err_free:
free (nametbl);
err_unmap:
arc_mmap_unmap (archdr, headersz, NULL);
err:
/* We report errors into the first file in the archive, if any: if this is a
zero-file archive, put it in the open-errors stream for lack of anywhere
else for it to go. */
ctf_err_warn (ctf_dict_cnt > 0 ? ctf_dicts[0] : NULL, 0, errno, "%s",
gettext (errmsg));
return errno;
}
/* Write out a CTF archive. The entries in CTF_DICTS are referenced by name:
the names are passed in the names array, which must have CTF_DICTS entries.
If the filename is NULL, create a temporary file and return a pointer to it.
Returns 0 on success, or an errno, or an ECTF_* value. */
int
ctf_arc_write (const char *file, ctf_dict_t **ctf_dicts, size_t ctf_dict_cnt,
const char **names, size_t threshold)
{
int err;
int fd;
if ((fd = open (file, O_RDWR | O_CREAT | O_TRUNC | O_CLOEXEC, 0666)) < 0)
{
ctf_err_warn (ctf_dict_cnt > 0 ? ctf_dicts[0] : NULL, 0, errno,
_("ctf_arc_write(): cannot create %s"), file);
return errno;
}
err = ctf_arc_write_fd (fd, ctf_dicts, ctf_dict_cnt, names, threshold);
if (err)
goto err_close;
if ((err = close (fd)) < 0)
ctf_err_warn (ctf_dict_cnt > 0 ? ctf_dicts[0] : NULL, 0, errno,
_("ctf_arc_write(): cannot close after writing to archive"));
goto err;
err_close:
(void) close (fd);
err:
if (err < 0)
unlink (file);
return err;
}
/* Write one CTF dict out. Return the file position of the written file (or
rather, of the file-size uint64_t that precedes it): negative return is a
negative errno or ctf_errno value. On error, the file position may no longer
be at the end of the file. */
static off_t
arc_write_one_ctf (ctf_dict_t *f, int fd, size_t threshold)
{
off_t off, end_off;
uint64_t ctfsz = 0;
char *ctfszp;
size_t ctfsz_len;
if ((off = lseek (fd, 0, SEEK_CUR)) < 0)
return errno * -1;
/* This zero-write turns into the size in a moment. */
ctfsz_len = sizeof (ctfsz);
ctfszp = (char *) &ctfsz;
while (ctfsz_len > 0)
{
ssize_t writelen = write (fd, ctfszp, ctfsz_len);
if (writelen < 0)
return errno * -1;
ctfsz_len -= writelen;
ctfszp += writelen;
}
if (ctf_write_thresholded (f, fd, threshold) != 0)
return f->ctf_errno * -1;
if ((end_off = lseek (fd, 0, SEEK_CUR)) < 0)
return errno * -1;
ctfsz = htole64 (end_off - off);
if ((lseek (fd, off, SEEK_SET)) < 0)
return errno * -1;
/* ... here. */
ctfsz_len = sizeof (ctfsz);
ctfszp = (char *) &ctfsz;
while (ctfsz_len > 0)
{
ssize_t writelen = write (fd, ctfszp, ctfsz_len);
if (writelen < 0)
return errno * -1;
ctfsz_len -= writelen;
ctfszp += writelen;
}
end_off = LCTF_ALIGN_OFFS (end_off, 8);
if ((lseek (fd, end_off, SEEK_SET)) < 0)
return errno * -1;
return off;
}
/* qsort() function to sort the array of struct ctf_archive_modents into
ascending name order. */
static int
sort_modent_by_name (const void *one, const void *two, void *n)
{
const struct ctf_archive_modent *a = one;
const struct ctf_archive_modent *b = two;
char *nametbl = n;
return strcmp (&nametbl[le64toh (a->name_offset)],
&nametbl[le64toh (b->name_offset)]);
}
/* bsearch_r() function to search for a given name in the sorted array of struct
ctf_archive_modents. */
static int
search_modent_by_name (const void *key, const void *ent, void *arg)
{
const char *k = key;
const struct ctf_archive_modent *v = ent;
const char *search_nametbl = arg;
return strcmp (k, &search_nametbl[le64toh (v->name_offset)]);
}
/* Make a new struct ctf_archive_internal wrapper for a ctf_archive or a
ctf_dict. Closes ARC and/or FP on error. Arrange to free the SYMSECT or
STRSECT, as needed, on close. Possibly do not unmap on close. */
struct ctf_archive_internal *
ctf_new_archive_internal (int is_archive, int unmap_on_close,
struct ctf_archive *arc,
ctf_dict_t *fp, const ctf_sect_t *symsect,
const ctf_sect_t *strsect,
int *errp)
{
struct ctf_archive_internal *arci;
if ((arci = calloc (1, sizeof (struct ctf_archive_internal))) == NULL)
{
if (is_archive)
{
if (unmap_on_close)
ctf_arc_close_internal (arc);
}
else
ctf_dict_close (fp);
return (ctf_set_open_errno (errp, errno));
}
arci->ctfi_is_archive = is_archive;
if (is_archive)
arci->ctfi_archive = arc;
else
arci->ctfi_dict = fp;
if (symsect)
memcpy (&arci->ctfi_symsect, symsect, sizeof (struct ctf_sect));
if (strsect)
memcpy (&arci->ctfi_strsect, strsect, sizeof (struct ctf_sect));
arci->ctfi_free_symsect = 0;
arci->ctfi_free_strsect = 0;
arci->ctfi_unmap_on_close = unmap_on_close;
arci->ctfi_symsect_little_endian = -1;
return arci;
}
/* Set the symbol-table endianness of an archive (defaulting the symtab
endianness of all ctf_file_t's opened from that archive). */
void
ctf_arc_symsect_endianness (ctf_archive_t *arc, int little_endian)
{
arc->ctfi_symsect_little_endian = !!little_endian;
if (!arc->ctfi_is_archive)
ctf_symsect_endianness (arc->ctfi_dict, arc->ctfi_symsect_little_endian);
}
/* Get the CTF preamble from data in a buffer, which may be either an archive or
a CTF dict. If multiple dicts are present in an archive, the preamble comes
from an arbitrary dict. The preamble is a pointer into the ctfsect passed
in. */
const ctf_preamble_t *
ctf_arc_bufpreamble (const ctf_sect_t *ctfsect)
{
if (ctfsect->cts_data != NULL
&& ctfsect->cts_size > sizeof (uint64_t)
&& (le64toh ((*(uint64_t *) ctfsect->cts_data)) == CTFA_MAGIC))
{
struct ctf_archive *arc = (struct ctf_archive *) ctfsect->cts_data;
return (const ctf_preamble_t *) ((char *) arc + le64toh (arc->ctfa_ctfs)
+ sizeof (uint64_t));
}
else
return (const ctf_preamble_t *) ctfsect->cts_data;
}
/* Open a CTF archive or dictionary from data in a buffer (which the caller must
preserve until ctf_arc_close() time). Returns the archive, or NULL and an
error in *err (if not NULL). */
ctf_archive_t *
ctf_arc_bufopen (const ctf_sect_t *ctfsect, const ctf_sect_t *symsect,
const ctf_sect_t *strsect, int *errp)
{
struct ctf_archive *arc = NULL;
int is_archive;
ctf_dict_t *fp = NULL;
if (ctfsect->cts_data != NULL
&& ctfsect->cts_size > sizeof (uint64_t)
&& (le64toh ((*(uint64_t *) ctfsect->cts_data)) == CTFA_MAGIC))
{
/* The archive is mmappable, so this operation is trivial.
This buffer is nonmodifiable, so the trick involving mmapping only part
of it and storing the length in the magic number is not applicable: so
record this fact in the archive-wrapper header. (We cannot record it
in the archive, because the archive may very well be a read-only
mapping.) */
is_archive = 1;
arc = (struct ctf_archive *) ctfsect->cts_data;
}
else
{
is_archive = 0;
if ((fp = ctf_bufopen (ctfsect, symsect, strsect, errp)) == NULL)
{
ctf_err_warn (NULL, 0, *errp, _("ctf_arc_bufopen(): cannot open CTF"));
return NULL;
}
}
return ctf_new_archive_internal (is_archive, 0, arc, fp, symsect, strsect,
errp);
}
/* Open a CTF archive. Returns the archive, or NULL and an error in *err (if
not NULL). */
struct ctf_archive *
ctf_arc_open_internal (const char *filename, int *errp)
{
const char *errmsg;
int fd;
struct stat s;
struct ctf_archive *arc; /* (Actually the whole file.) */
libctf_init_debug();
if ((fd = open (filename, O_RDONLY)) < 0)
{
errmsg = N_("ctf_arc_open(): cannot open %s");
goto err;
}
if (fstat (fd, &s) < 0)
{
errmsg = N_("ctf_arc_open(): cannot stat %s");
goto err_close;
}
if ((arc = arc_mmap_file (fd, s.st_size)) == NULL)
{
errmsg = N_("ctf_arc_open(): cannot read in %s");
goto err_close;
}
if (le64toh (arc->ctfa_magic) != CTFA_MAGIC)
{
errmsg = N_("ctf_arc_open(): %s: invalid magic number");
errno = ECTF_FMT;
goto err_unmap;
}
/* This horrible hack lets us know how much to unmap when the file is
closed. (We no longer need the magic number, and the mapping
is private.) */
arc->ctfa_magic = s.st_size;
close (fd);
return arc;
err_unmap:
arc_mmap_unmap (arc, s.st_size, NULL);
err_close:
close (fd);
err:
if (errp)
*errp = errno;
ctf_err_warn (NULL, 0, errno, gettext (errmsg), filename);
return NULL;
}
/* Close an archive. */
void
ctf_arc_close_internal (struct ctf_archive *arc)
{
if (arc == NULL)
return;
/* See the comment in ctf_arc_open(). */
arc_mmap_unmap (arc, arc->ctfa_magic, NULL);
}
/* Public entry point: close an archive, or CTF file. */
void
ctf_arc_close (ctf_archive_t *arc)
{
if (arc == NULL)
return;
if (arc->ctfi_is_archive)
{
if (arc->ctfi_unmap_on_close)
ctf_arc_close_internal (arc->ctfi_archive);
}
else
ctf_dict_close (arc->ctfi_dict);
free (arc->ctfi_symdicts);
free (arc->ctfi_symnamedicts);
ctf_dynhash_destroy (arc->ctfi_dicts);
if (arc->ctfi_free_symsect)
free ((void *) arc->ctfi_symsect.cts_data);
if (arc->ctfi_free_strsect)
free ((void *) arc->ctfi_strsect.cts_data);
free (arc->ctfi_data);
if (arc->ctfi_bfd_close)
arc->ctfi_bfd_close (arc);
free (arc);
}
/* Return the ctf_dict_t with the given name, or NULL if none, setting 'err' if
non-NULL. A name of NULL means to open the default file. */
static ctf_dict_t *
ctf_dict_open_internal (const struct ctf_archive *arc,
const ctf_sect_t *symsect,
const ctf_sect_t *strsect,
const char *name, int little_endian,
int *errp)
{
struct ctf_archive_modent *modent;
const char *search_nametbl;
if (name == NULL)
name = _CTF_SECTION; /* The default name. */
ctf_dprintf ("ctf_dict_open_internal(%s): opening\n", name);
modent = (ctf_archive_modent_t *) ((char *) arc
+ sizeof (struct ctf_archive));
search_nametbl = (const char *) arc + le64toh (arc->ctfa_names);
modent = bsearch_r (name, modent, le64toh (arc->ctfa_ndicts),
sizeof (struct ctf_archive_modent),
search_modent_by_name, (void *) search_nametbl);
/* This is actually a common case and normal operation: no error
debug output. */
if (modent == NULL)
{
if (errp)
*errp = ECTF_ARNNAME;
return NULL;
}
return ctf_dict_open_by_offset (arc, symsect, strsect,
le64toh (modent->ctf_offset),
little_endian, errp);
}
/* Return the ctf_dict_t with the given name, or NULL if none, setting 'err' if
non-NULL. A name of NULL means to open the default file.
Use the specified string and symbol table sections.
Public entry point. */
ctf_dict_t *
ctf_dict_open_sections (const ctf_archive_t *arc,
const ctf_sect_t *symsect,
const ctf_sect_t *strsect,
const char *name,
int *errp)
{
if (arc->ctfi_is_archive)
{
ctf_dict_t *ret;
ret = ctf_dict_open_internal (arc->ctfi_archive, symsect, strsect,
name, arc->ctfi_symsect_little_endian,
errp);
if (ret)
{
ret->ctf_archive = (ctf_archive_t *) arc;
if (ctf_arc_import_parent (arc, ret, errp) < 0)
{
ctf_dict_close (ret);
return NULL;
}
}
return ret;
}
if ((name != NULL) && (strcmp (name, _CTF_SECTION) != 0))
{
if (errp)
*errp = ECTF_ARNNAME;
return NULL;
}
arc->ctfi_dict->ctf_archive = (ctf_archive_t *) arc;
/* Bump the refcount so that the user can ctf_dict_close() it. */
arc->ctfi_dict->ctf_refcnt++;
return arc->ctfi_dict;
}
/* Return the ctf_dict_t with the given name, or NULL if none, setting 'err' if
non-NULL. A name of NULL means to open the default file.
Public entry point. */
ctf_dict_t *
ctf_dict_open (const ctf_archive_t *arc, const char *name, int *errp)
{
const ctf_sect_t *symsect = &arc->ctfi_symsect;
const ctf_sect_t *strsect = &arc->ctfi_strsect;
if (symsect->cts_name == NULL)
symsect = NULL;
if (strsect->cts_name == NULL)
strsect = NULL;
return ctf_dict_open_sections (arc, symsect, strsect, name, errp);
}
static void
ctf_cached_dict_close (void *fp)
{
ctf_dict_close ((ctf_dict_t *) fp);
}
/* Return the ctf_dict_t with the given name and cache it in the archive's
ctfi_dicts. If this is the first cached dict, designate it the
crossdict_cache. */
static ctf_dict_t *
ctf_dict_open_cached (ctf_archive_t *arc, const char *name, int *errp)
{
ctf_dict_t *fp;
char *dupname;
/* Just return from the cache if possible. */
if (arc->ctfi_dicts
&& ((fp = ctf_dynhash_lookup (arc->ctfi_dicts, name)) != NULL))
{
fp->ctf_refcnt++;
return fp;
}
/* Not yet cached: open it. */
fp = ctf_dict_open (arc, name, errp);
dupname = strdup (name);
if (!fp || !dupname)
goto oom;
if (arc->ctfi_dicts == NULL)
if ((arc->ctfi_dicts
= ctf_dynhash_create (ctf_hash_string, ctf_hash_eq_string,
free, ctf_cached_dict_close)) == NULL)
goto oom;
if (ctf_dynhash_insert (arc->ctfi_dicts, dupname, fp) < 0)
goto oom;
fp->ctf_refcnt++;
if (arc->ctfi_crossdict_cache == NULL)
arc->ctfi_crossdict_cache = fp;
/* If this archive has multiple members, and this is a parent, pretend
that we have opened at least one child. This forces type and string
allocations in the parent to use provisional IDs, permitting you to
import children into it even if you modify the parent before you import
any. */
if (arc->ctfi_is_archive && arc->ctfi_archive->ctfa_ndicts > 1
&& !(fp->ctf_flags & LCTF_CHILD))
{
ctf_dprintf ("archived parent: max children bumped.\n");
fp->ctf_max_children++;
}
return fp;
oom:
ctf_dict_close (fp);
free (dupname);
if (errp)
*errp = ENOMEM;
return NULL;
}
/* Flush any caches the CTF archive may have open. */
void
ctf_arc_flush_caches (ctf_archive_t *wrapper)
{
free (wrapper->ctfi_symdicts);
ctf_dynhash_destroy (wrapper->ctfi_symnamedicts);
ctf_dynhash_destroy (wrapper->ctfi_dicts);
wrapper->ctfi_symdicts = NULL;
wrapper->ctfi_symnamedicts = NULL;
wrapper->ctfi_dicts = NULL;
wrapper->ctfi_crossdict_cache = NULL;
}
/* Return the ctf_dict_t at the given ctfa_ctfs-relative offset, or NULL if
none, setting 'err' if non-NULL. */
static ctf_dict_t *
ctf_dict_open_by_offset (const struct ctf_archive *arc,
const ctf_sect_t *symsect,
const ctf_sect_t *strsect, size_t offset,
int little_endian, int *errp)
{
ctf_sect_t ctfsect;
ctf_dict_t *fp;
ctf_dprintf ("ctf_dict_open_by_offset(%lu): opening\n", (unsigned long) offset);
memset (&ctfsect, 0, sizeof (ctf_sect_t));
offset += le64toh (arc->ctfa_ctfs);
ctfsect.cts_name = _CTF_SECTION;
ctfsect.cts_size = le64toh (*((uint64_t *) ((char *) arc + offset)));
ctfsect.cts_entsize = 1;
ctfsect.cts_data = (void *) ((char *) arc + offset + sizeof (uint64_t));
fp = ctf_bufopen (&ctfsect, symsect, strsect, errp);
if (fp)
{
ctf_setmodel (fp, le64toh (arc->ctfa_model));
if (little_endian >= 0)
ctf_symsect_endianness (fp, little_endian);
}
return fp;
}
/* Backward compatibility. */
ctf_dict_t *
ctf_arc_open_by_name (const ctf_archive_t *arc, const char *name,
int *errp)
{
return ctf_dict_open (arc, name, errp);
}
ctf_dict_t *
ctf_arc_open_by_name_sections (const ctf_archive_t *arc,
const ctf_sect_t *symsect,
const ctf_sect_t *strsect,
const char *name,
int *errp)
{
return ctf_dict_open_sections (arc, symsect, strsect, name, errp);
}
/* Import the parent into a ctf archive, if this is a child, the parent is not
already set, and a suitable archive member exists. No error is raised if
this is not possible: this is just a best-effort helper operation to give
people useful dicts to start with. */
static int
ctf_arc_import_parent (const ctf_archive_t *arc, ctf_dict_t *fp, int *errp)
{
if ((fp->ctf_flags & LCTF_CHILD) && fp->ctf_parname && !fp->ctf_parent)
{
int err;
ctf_dict_t *parent = ctf_dict_open_cached ((ctf_archive_t *) arc,
fp->ctf_parname, &err);
if (errp)
*errp = err;
if (parent)
{
if (ctf_import (fp, parent) < 0)
ctf_err_warn (NULL, 1, ctf_errno (fp),
"ctf_arc_import_parent: cannot import: %s",
ctf_errmsg (ctf_errno (fp)));
ctf_dict_close (parent);
}
else if (err != ECTF_ARNNAME)
return -1; /* errno is set for us. */
}
return 0;
}
/* Return the number of members in an archive. */
size_t
ctf_archive_count (const ctf_archive_t *wrapper)
{
if (!wrapper->ctfi_is_archive)
return 1;
return le64toh (wrapper->ctfi_archive->ctfa_ndicts);
}
/* Look up a symbol in an archive by name or index (if the name is set, a lookup
by name is done). Return the dict in the archive that the symbol is found
in, and (optionally) the ctf_id_t of the symbol in that dict (so you don't
have to look it up yourself). The dict is cached, so repeated lookups are
nearly free.
As usual, you should ctf_dict_close() the returned dict once you are done
with it.
Returns NULL on error, and an error in errp (if set). */
static ctf_dict_t *
ctf_arc_lookup_sym_or_name (ctf_archive_t *wrapper, unsigned long symidx,
const char *symname, ctf_id_t *typep, int *errp)
{
ctf_dict_t *fp;
void *fpkey;
ctf_id_t type;
/* The usual non-archive-transparent-wrapper special case. */
if (!wrapper->ctfi_is_archive)
{
if (!symname)
{
if ((type = ctf_lookup_by_symbol (wrapper->ctfi_dict, symidx)) == CTF_ERR)
{
if (errp)
*errp = ctf_errno (wrapper->ctfi_dict);
return NULL;
}
}
else
{
if ((type = ctf_lookup_by_symbol_name (wrapper->ctfi_dict,
symname)) == CTF_ERR)
{
if (errp)
*errp = ctf_errno (wrapper->ctfi_dict);
return NULL;
}
}
if (typep)
*typep = type;
wrapper->ctfi_dict->ctf_refcnt++;
return wrapper->ctfi_dict;
}
if (wrapper->ctfi_symsect.cts_name == NULL
|| wrapper->ctfi_symsect.cts_data == NULL
|| wrapper->ctfi_symsect.cts_size == 0
|| wrapper->ctfi_symsect.cts_entsize == 0)
{
if (errp)
*errp = ECTF_NOSYMTAB;
return NULL;
}
/* Make enough space for all possible symbol indexes, if not already done. We
cache the originating dictionary of all symbols. The dict links are weak,
to the dictionaries cached in ctfi_dicts: their refcnts are *not* bumped.
We also cache similar mappings for symbol names: these are ordinary
dynhashes, with weak links to dicts. */
if (!wrapper->ctfi_symdicts)
{
if ((wrapper->ctfi_symdicts = calloc (wrapper->ctfi_symsect.cts_size
/ wrapper->ctfi_symsect.cts_entsize,
sizeof (ctf_dict_t *))) == NULL)
{
if (errp)
*errp = ENOMEM;
return NULL;
}
}
if (!wrapper->ctfi_symnamedicts)
{
if ((wrapper->ctfi_symnamedicts = ctf_dynhash_create (ctf_hash_string,
ctf_hash_eq_string,
free, NULL)) == NULL)
{
if (errp)
*errp = ENOMEM;
return NULL;
}
}
/* Perhaps the dict in which we found a previous lookup is cached. If it's
supposed to be cached but we don't find it, pretend it was always not
found: this should never happen, but shouldn't be allowed to cause trouble
if it does. */
if ((symname && ctf_dynhash_lookup_kv (wrapper->ctfi_symnamedicts,
symname, NULL, &fpkey))
|| (!symname && wrapper->ctfi_symdicts[symidx] != NULL))
{
if (symname)
fp = (ctf_dict_t *) fpkey;
else
fp = wrapper->ctfi_symdicts[symidx];
if (fp == &enosym)
goto no_sym;
if (symname)
{
if ((type = ctf_lookup_by_symbol_name (fp, symname)) == CTF_ERR)
goto cache_no_sym;
}
else
{
if ((type = ctf_lookup_by_symbol (fp, symidx)) == CTF_ERR)
goto cache_no_sym;
}
if (typep)
*typep = type;
fp->ctf_refcnt++;
return fp;
}
/* Not cached: find it and cache it. We must track open errors ourselves even
if our caller doesn't, to be able to distinguish no-error end-of-iteration
from open errors. */
int local_err;
int *local_errp;
ctf_next_t *i = NULL;
const char *name;
if (errp)
local_errp = errp;
else
local_errp = &local_err;
while ((fp = ctf_archive_next (wrapper, &i, &name, 0, local_errp)) != NULL)
{
if (!symname)
{
if ((type = ctf_lookup_by_symbol (fp, symidx)) != CTF_ERR)
wrapper->ctfi_symdicts[symidx] = fp;
}
else
{
if ((type = ctf_lookup_by_symbol_name (fp, symname)) != CTF_ERR)
{
char *tmp;
/* No error checking, as above. */
if ((tmp = strdup (symname)) != NULL)
ctf_dynhash_insert (wrapper->ctfi_symnamedicts, tmp, fp);
}
}
if (type != CTF_ERR)
{
if (typep)
*typep = type;
ctf_next_destroy (i);
return fp;
}
if (ctf_errno (fp) != ECTF_NOTYPEDAT)
{
if (errp)
*errp = ctf_errno (fp);
ctf_dict_close (fp);
ctf_next_destroy (i);
return NULL; /* errno is set for us. */
}
ctf_dict_close (fp);
}
if (*local_errp != ECTF_NEXT_END)
{
ctf_next_destroy (i);
return NULL;
}
/* Don't leak end-of-iteration to the caller. */
*local_errp = 0;
cache_no_sym:
if (!symname)
wrapper->ctfi_symdicts[symidx] = &enosym;
else
{
char *tmp;
/* No error checking: if caching fails, there is only a slight performance
impact. */
if ((tmp = strdup (symname)) != NULL)
if (ctf_dynhash_insert (wrapper->ctfi_symnamedicts, tmp, &enosym) < 0)
free (tmp);
}
no_sym:
if (errp)
*errp = ECTF_NOTYPEDAT;
if (typep)
*typep = CTF_ERR;
return NULL;
}
/* The public API for looking up a symbol by index. */
ctf_dict_t *
ctf_arc_lookup_symbol (ctf_archive_t *wrapper, unsigned long symidx,
ctf_id_t *typep, int *errp)
{
return ctf_arc_lookup_sym_or_name (wrapper, symidx, NULL, typep, errp);
}
/* The public API for looking up a symbol by name. */
ctf_dict_t *
ctf_arc_lookup_symbol_name (ctf_archive_t *wrapper, const char *symname,
ctf_id_t *typep, int *errp)
{
return ctf_arc_lookup_sym_or_name (wrapper, 0, symname, typep, errp);
}
/* Return all enumeration constants with a given NAME across all dicts in an
archive, similar to ctf_lookup_enumerator_next. The DICT is cached, so
opening costs are paid only once, but (unlike ctf_arc_lookup_symbol*
above) the results of the iterations are not cached. dict and errp are
not optional. */
ctf_id_t
ctf_arc_lookup_enumerator_next (ctf_archive_t *arc, const char *name,
ctf_next_t **it, int64_t *enum_value,
ctf_dict_t **dict, int *errp)
{
ctf_next_t *i = *it;
ctf_id_t type;
int opened_this_time = 0;
int err;
/* We have two nested iterators in here: ctn_next tracks archives, while
within it ctn_next_inner tracks enumerators within an archive. We
keep track of the dict by simply reusing the passed-in arg: if it's
changed by the caller, the caller will get an ECTF_WRONGFP error,
so this is quite safe and means we don't have to track the arc and fp
simultaneously in the ctf_next_t. */
if (!i)
{
if ((i = ctf_next_create ()) == NULL)
{
err = ENOMEM;
goto err;
}
i->ctn_iter_fun = (void (*) (void)) ctf_arc_lookup_enumerator_next;
i->cu.ctn_arc = arc;
*it = i;
}
if ((void (*) (void)) ctf_arc_lookup_enumerator_next != i->ctn_iter_fun)
{
err = ECTF_NEXT_WRONGFUN;
goto err;
}
if (arc != i->cu.ctn_arc)
{
err = ECTF_NEXT_WRONGFP;
goto err;
}
/* Prevent any earlier end-of-iteration on this dict from confusing the
test below. */
if (i->ctn_next != NULL)
ctf_set_errno (*dict, 0);
do
{
/* At end of one dict, or not started any iterations yet?
Traverse to next dict. If we never returned this dict to the
caller, close it ourselves: the caller will never see it and cannot
do so. */
if (i->ctn_next == NULL || ctf_errno (*dict) == ECTF_NEXT_END)
{
if (opened_this_time)
{
ctf_dict_close (*dict);
*dict = NULL;
opened_this_time = 0;
}
*dict = ctf_archive_next (arc, &i->ctn_next, NULL, 0, &err);
if (!*dict)
goto err;
opened_this_time = 1;
}
type = ctf_lookup_enumerator_next (*dict, name, &i->ctn_next_inner,
enum_value);
}
while (type == CTF_ERR && ctf_errno (*dict) == ECTF_NEXT_END);
if (type == CTF_ERR)
{
err = ctf_errno (*dict);
goto err;
}
/* If this dict is being reused from the previous iteration, bump its
refcnt: the caller is going to close it and has no idea that we didn't
open it this time round. */
if (!opened_this_time)
ctf_ref (*dict);
return type;
err: /* Also ECTF_NEXT_END. */
if (opened_this_time)
{
ctf_dict_close (*dict);
*dict = NULL;
}
ctf_next_destroy (i);
*it = NULL;
if (errp)
*errp = err;
return CTF_ERR;
}
/* Raw iteration over all CTF files in an archive. We pass the raw data for all
CTF files in turn to the specified callback function. */
static int
ctf_archive_raw_iter_internal (const struct ctf_archive *arc,
ctf_archive_raw_member_f *func, void *data)
{
int rc;
size_t i;
struct ctf_archive_modent *modent;
const char *nametbl;
modent = (ctf_archive_modent_t *) ((char *) arc
+ sizeof (struct ctf_archive));
nametbl = (((const char *) arc) + le64toh (arc->ctfa_names));
for (i = 0; i < le64toh (arc->ctfa_ndicts); i++)
{
const char *name;
char *fp;
name = &nametbl[le64toh (modent[i].name_offset)];
fp = ((char *) arc + le64toh (arc->ctfa_ctfs)
+ le64toh (modent[i].ctf_offset));
if ((rc = func (name, (void *) (fp + sizeof (uint64_t)),
le64toh (*((uint64_t *) fp)), data)) != 0)
return rc;
}
return 0;
}
/* Raw iteration over all CTF files in an archive: public entry point.
Returns -EINVAL if not supported for this sort of archive. */
int
ctf_archive_raw_iter (const ctf_archive_t *arc,
ctf_archive_raw_member_f * func, void *data)
{
if (arc->ctfi_is_archive)
return ctf_archive_raw_iter_internal (arc->ctfi_archive, func, data);
return -EINVAL; /* Not supported. */
}
/* Iterate over all CTF files in an archive: public entry point. We pass all
CTF files in turn to the specified callback function. */
int
ctf_archive_iter (const ctf_archive_t *arc, ctf_archive_member_f *func,
void *data)
{
ctf_next_t *i = NULL;
ctf_dict_t *fp;
const char *name;
int err = 0;
while ((fp = ctf_archive_next (arc, &i, &name, 0, &err)) != NULL)
{
int rc;
if ((rc = func (fp, name, data)) != 0)
{
ctf_dict_close (fp);
ctf_next_destroy (i);
return rc;
}
ctf_dict_close (fp);
}
if (err != ECTF_NEXT_END && err != 0)
{
ctf_next_destroy (i);
return -1;
}
return 0;
}
/* Iterate over all CTF files in an archive, returning each dict in turn as a
ctf_dict_t, and NULL on error or end of iteration. It is the caller's
responsibility to close it. Parent dicts may be skipped.
The archive member is cached for rapid return on future calls.
We identify parents by name rather than by flag value: for now, with the
linker only emitting parents named _CTF_SECTION, this works well enough. */
ctf_dict_t *
ctf_archive_next (const ctf_archive_t *wrapper, ctf_next_t **it, const char **name,
int skip_parent, int *errp)
{
ctf_dict_t *f;
ctf_next_t *i = *it;
struct ctf_archive *arc;
struct ctf_archive_modent *modent;
const char *nametbl;
const char *name_;
if (!i)
{
if ((i = ctf_next_create()) == NULL)
{
if (errp)
*errp = ENOMEM;
return NULL;
}
i->cu.ctn_arc = wrapper;
i->ctn_iter_fun = (void (*) (void)) ctf_archive_next;
*it = i;
}
if ((void (*) (void)) ctf_archive_next != i->ctn_iter_fun)
{
if (errp)
*errp = ECTF_NEXT_WRONGFUN;
return NULL;
}
if (wrapper != i->cu.ctn_arc)
{
if (errp)
*errp = ECTF_NEXT_WRONGFP;
return NULL;
}
/* Iteration is made a bit more complex by the need to handle ctf_dict_t's
transparently wrapped in a single-member archive. These are parents: if
skip_parent is on, they are skipped and the iterator terminates
immediately. */
if (!wrapper->ctfi_is_archive && i->ctn_n == 0)
{
i->ctn_n++;
if (!skip_parent)
{
wrapper->ctfi_dict->ctf_refcnt++;
if (name)
*name = _CTF_SECTION;
return wrapper->ctfi_dict;
}
}
arc = wrapper->ctfi_archive;
/* The loop keeps going when skip_parent is on as long as the member we find
is the parent (i.e. at most two iterations, but possibly an early return if
*all* we have is a parent). */
do
{
if ((!wrapper->ctfi_is_archive) || (i->ctn_n >= le64toh (arc->ctfa_ndicts)))
{
ctf_next_destroy (i);
*it = NULL;
if (errp)
*errp = ECTF_NEXT_END;
return NULL;
}
modent = (ctf_archive_modent_t *) ((char *) arc
+ sizeof (struct ctf_archive));
nametbl = (((const char *) arc) + le64toh (arc->ctfa_names));
name_ = &nametbl[le64toh (modent[i->ctn_n].name_offset)];
i->ctn_n++;
}
while (skip_parent && strcmp (name_, _CTF_SECTION) == 0);
if (name)
*name = name_;
f = ctf_dict_open_cached ((ctf_archive_t *) wrapper, name_, errp);
return f;
}
#ifdef HAVE_MMAP
/* Map the header in. Only used on new, empty files. */
static void *arc_mmap_header (int fd, size_t headersz)
{
void *hdr;
if ((hdr = mmap (NULL, headersz, PROT_READ | PROT_WRITE, MAP_SHARED, fd,
0)) == MAP_FAILED)
return NULL;
return hdr;
}
/* mmap() the whole file, for reading only. (Map it writably, but privately: we
need to modify the region, but don't need anyone else to see the
modifications.) */
static void *arc_mmap_file (int fd, size_t size)
{
void *arc;
if ((arc = mmap (NULL, size, PROT_READ | PROT_WRITE, MAP_PRIVATE,
fd, 0)) == MAP_FAILED)
return NULL;
return arc;
}
/* Persist the header to disk. */
static int arc_mmap_writeout (int fd _libctf_unused_, void *header,
size_t headersz, const char **errmsg)
{
if (msync (header, headersz, MS_ASYNC) < 0)
{
if (errmsg)
*errmsg = N_("arc_mmap_writeout(): cannot sync after writing "
"to %s: %s");
return -1;
}
return 0;
}
/* Unmap the region. */
static int arc_mmap_unmap (void *header, size_t headersz, const char **errmsg)
{
if (munmap (header, headersz) < 0)
{
if (errmsg)
*errmsg = N_("arc_mmap_munmap(): cannot unmap after writing "
"to %s: %s");
return -1;
}
return 0;
}
#else
/* Map the header in. Only used on new, empty files. */
static void *arc_mmap_header (int fd _libctf_unused_, size_t headersz)
{
void *hdr;
if ((hdr = malloc (headersz)) == NULL)
return NULL;
return hdr;
}
/* Pull in the whole file, for reading only. We assume the current file
position is at the start of the file. */
static void *arc_mmap_file (int fd, size_t size)
{
char *data;
if ((data = malloc (size)) == NULL)
return NULL;
if (ctf_pread (fd, data, size, 0) < 0)
{
free (data);
return NULL;
}
return data;
}
/* Persist the header to disk. */
static int arc_mmap_writeout (int fd, void *header, size_t headersz,
const char **errmsg)
{
ssize_t len;
char *data = (char *) header;
ssize_t count = headersz;
if ((lseek (fd, 0, SEEK_SET)) < 0)
{
if (errmsg)
*errmsg = N_("arc_mmap_writeout(): cannot seek while writing header to "
"%s: %s");
return -1;
}
while (headersz > 0)
{
if ((len = write (fd, data, count)) < 0)
{
if (errmsg)
*errmsg = N_("arc_mmap_writeout(): cannot write header to %s: %s");
return len;
}
if (len == EINTR)
continue;
if (len == 0) /* EOF. */
break;
count -= len;
data += len;
}
return 0;
}
/* Unmap the region. */
static int arc_mmap_unmap (void *header, size_t headersz _libctf_unused_,
const char **errmsg _libctf_unused_)
{
free (header);
return 0;
}
#endif
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