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9402cc593f
binutils-gdb/libctf/ctf-open.c
Nick Alcock 9402cc593f libctf: mmappable archives 
If you need to store a large number of CTF containers somewhere, this
provides a dedicated facility for doing so: an mmappable archive format
like a very simple tar or ar without all the system-dependent format
horrors or need for heavy file copying, with built-in compression of
files above a particular size threshold.

libctf automatically mmap()s uncompressed elements of these archives, or
uncompresses them, as needed.  (If the platform does not support mmap(),
copying into dynamically-allocated buffers is used.)

Archive iteration operations are partitioned into raw and non-raw
forms. Raw operations pass thhe raw archive contents to the callback:
non-raw forms open each member with ctf_bufopen() and pass the resulting
ctf_file_t to the iterator instead.  This lets you manipulate the raw
data in the archive, or the contents interpreted as a CTF file, as
needed.

It is not yet known whether we will store CTF archives in a linked ELF
object in one of these (akin to debugdata) or whether they'll get one
section per TU plus one parent container for types shared between them.
(In the case of ELF objects with very large numbers of TUs, an archive
of all of them would seem preferable, so we might just use an archive,
and add lzma support so you can assume that .gnu_debugdata and .ctf are
compressed using the same algorithm if both are present.)

To make usage easier, the ctf_archive_t is not the on-disk
representation but an abstraction over both ctf_file_t's and archives of
many ctf_file_t's: users see both CTF archives and raw CTF files as
ctf_archive_t's upon opening, the only difference being that a raw CTF
file has only a single "archive member", named ".ctf" (the default if a
null pointer is passed in as the name).  The next commit will make use
of this facility, in addition to providing the public interface to
actually open archives.  (In the future, it should be possible to have
all CTF sections in an ELF file appear as an "archive" in the same
fashion.)

This machinery is also used to allow library-internal creators of
ctf_archive_t's (such as the next commit) to stash away an ELF string
and symbol table, so that all opens of members in a given archive will
use them.  This lets CTF archives exploit the ELF string and symbol
table just like raw CTF files can.

(All this leads to somewhat confusing type naming.  The ctf_archive_t is
a typedef for the opaque internal type, struct ctf_archive_internal: the
non-internal "struct ctf_archive" is the on-disk structure meant for
other libraries manipulating CTF files.  It is probably clearest to use
the struct name for struct ctf_archive_internal inside the program, and
the typedef names outside.)

libctf/
	* ctf-archive.c: New.
	* ctf-impl.h (ctf_archive_internal): New type.
	(ctf_arc_open_internal): New declaration.
	(ctf_arc_bufopen): Likewise.
	(ctf_arc_close_internal): Likewise.
include/
	* ctf.h (CTFA_MAGIC): New.
	(struct ctf_archive): New.
	(struct ctf_archive_modent): Likewise.
	* ctf-api.h (ctf_archive_member_f): New.
	(ctf_archive_raw_member_f): Likewise.
	(ctf_arc_write): Likewise.
	(ctf_arc_close): Likewise.
	(ctf_arc_open_by_name): Likewise.
	(ctf_archive_iter): Likewise.
	(ctf_archive_raw_iter): Likewise.
	(ctf_get_arc): Likewise.
2019-05-28 17:07:55 +01:00

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/* Opening CTF files.
Copyright (C) 2019 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 <stddef.h>
#include <string.h>
#include <sys/types.h>
#include <elf.h>
#include <assert.h>
#include "swap.h"
#include <bfd.h>
#include <zlib.h>
#include "elf-bfd.h"
static const ctf_dmodel_t _libctf_models[] = {
{"ILP32", CTF_MODEL_ILP32, 4, 1, 2, 4, 4},
{"LP64", CTF_MODEL_LP64, 8, 1, 2, 4, 8},
{NULL, 0, 0, 0, 0, 0, 0}
};
const char _CTF_SECTION[] = ".ctf";
const char _CTF_NULLSTR[] = "";
/* Version-sensitive accessors. */
static uint32_t
get_kind_v1 (uint32_t info)
{
return (CTF_V1_INFO_KIND (info));
}
static uint32_t
get_root_v1 (uint32_t info)
{
return (CTF_V1_INFO_ISROOT (info));
}
static uint32_t
get_vlen_v1 (uint32_t info)
{
return (CTF_V1_INFO_VLEN (info));
}
static uint32_t
get_kind_v2 (uint32_t info)
{
return (CTF_V2_INFO_KIND (info));
}
static uint32_t
get_root_v2 (uint32_t info)
{
return (CTF_V2_INFO_ISROOT (info));
}
static uint32_t
get_vlen_v2 (uint32_t info)
{
return (CTF_V2_INFO_VLEN (info));
}
static inline ssize_t
get_ctt_size_common (const ctf_file_t *fp _libctf_unused_,
const ctf_type_t *tp _libctf_unused_,
ssize_t *sizep, ssize_t *incrementp, size_t lsize,
size_t csize, size_t ctf_type_size,
size_t ctf_stype_size, size_t ctf_lsize_sent)
{
ssize_t size, increment;
if (csize == ctf_lsize_sent)
{
size = lsize;
increment = ctf_type_size;
}
else
{
size = csize;
increment = ctf_stype_size;
}
if (sizep)
*sizep = size;
if (incrementp)
*incrementp = increment;
return size;
}
static ssize_t
get_ctt_size_v1 (const ctf_file_t *fp, const ctf_type_t *tp,
ssize_t *sizep, ssize_t *incrementp)
{
ctf_type_v1_t *t1p = (ctf_type_v1_t *) tp;
return (get_ctt_size_common (fp, tp, sizep, incrementp,
CTF_TYPE_LSIZE (t1p), t1p->ctt_size,
sizeof (ctf_type_v1_t), sizeof (ctf_stype_v1_t),
CTF_LSIZE_SENT_V1));
}
/* Return the size that a v1 will be once it is converted to v2. */
static ssize_t
get_ctt_size_v2_unconverted (const ctf_file_t *fp, const ctf_type_t *tp,
ssize_t *sizep, ssize_t *incrementp)
{
ctf_type_v1_t *t1p = (ctf_type_v1_t *) tp;
return (get_ctt_size_common (fp, tp, sizep, incrementp,
CTF_TYPE_LSIZE (t1p), t1p->ctt_size,
sizeof (ctf_type_t), sizeof (ctf_stype_t),
CTF_LSIZE_SENT));
}
static ssize_t
get_ctt_size_v2 (const ctf_file_t *fp, const ctf_type_t *tp,
ssize_t *sizep, ssize_t *incrementp)
{
return (get_ctt_size_common (fp, tp, sizep, incrementp,
CTF_TYPE_LSIZE (tp), tp->ctt_size,
sizeof (ctf_type_t), sizeof (ctf_stype_t),
CTF_LSIZE_SENT));
}
static ssize_t
get_vbytes_common (unsigned short kind, ssize_t size _libctf_unused_,
size_t vlen)
{
switch (kind)
{
case CTF_K_INTEGER:
case CTF_K_FLOAT:
return (sizeof (uint32_t));
case CTF_K_SLICE:
return (offsetof (ctf_slice_t, cts_bits) +
sizeof (((ctf_slice_t *)0)->cts_bits));
case CTF_K_ENUM:
return (sizeof (ctf_enum_t) * vlen);
case CTF_K_FORWARD:
case CTF_K_UNKNOWN:
case CTF_K_POINTER:
case CTF_K_TYPEDEF:
case CTF_K_VOLATILE:
case CTF_K_CONST:
case CTF_K_RESTRICT:
return 0;
default:
ctf_dprintf ("detected invalid CTF kind -- %x\n", kind);
return ECTF_CORRUPT;
}
}
static ssize_t
get_vbytes_v1 (unsigned short kind, ssize_t size, size_t vlen)
{
switch (kind)
{
case CTF_K_ARRAY:
return (sizeof (ctf_array_v1_t));
case CTF_K_FUNCTION:
return (sizeof (unsigned short) * (vlen + (vlen & 1)));
case CTF_K_STRUCT:
case CTF_K_UNION:
if (size < CTF_LSTRUCT_THRESH_V1)
return (sizeof (ctf_member_v1_t) * vlen);
else
return (sizeof (ctf_lmember_v1_t) * vlen);
}
return (get_vbytes_common (kind, size, vlen));
}
static ssize_t
get_vbytes_v2 (unsigned short kind, ssize_t size, size_t vlen)
{
switch (kind)
{
case CTF_K_ARRAY:
return (sizeof (ctf_array_t));
case CTF_K_FUNCTION:
return (sizeof (uint32_t) * (vlen + (vlen & 1)));
case CTF_K_STRUCT:
case CTF_K_UNION:
if (size < CTF_LSTRUCT_THRESH)
return (sizeof (ctf_member_t) * vlen);
else
return (sizeof (ctf_lmember_t) * vlen);
}
return (get_vbytes_common (kind, size, vlen));
}
static const ctf_fileops_t ctf_fileops[] = {
{NULL, NULL, NULL, NULL, NULL},
/* CTF_VERSION_1 */
{get_kind_v1, get_root_v1, get_vlen_v1, get_ctt_size_v1, get_vbytes_v1},
/* CTF_VERSION_1_UPGRADED_3 */
{get_kind_v2, get_root_v2, get_vlen_v2, get_ctt_size_v2, get_vbytes_v2},
/* CTF_VERSION_2 */
{get_kind_v2, get_root_v2, get_vlen_v2, get_ctt_size_v2, get_vbytes_v2},
/* CTF_VERSION_3, identical to 2: only new type kinds */
{get_kind_v2, get_root_v2, get_vlen_v2, get_ctt_size_v2, get_vbytes_v2},
};
/* Initialize the symtab translation table by filling each entry with the
offset of the CTF type or function data corresponding to each STT_FUNC or
STT_OBJECT entry in the symbol table. */
static int
init_symtab (ctf_file_t *fp, const ctf_header_t *hp,
const ctf_sect_t *sp, const ctf_sect_t *strp)
{
const unsigned char *symp = sp->cts_data;
uint32_t *xp = fp->ctf_sxlate;
uint32_t *xend = xp + fp->ctf_nsyms;
uint32_t objtoff = hp->cth_objtoff;
uint32_t funcoff = hp->cth_funcoff;
uint32_t info, vlen;
Elf64_Sym sym, *gsp;
const char *name;
/* The CTF data object and function type sections are ordered to match
the relative order of the respective symbol types in the symtab.
If no type information is available for a symbol table entry, a
pad is inserted in the CTF section. As a further optimization,
anonymous or undefined symbols are omitted from the CTF data. */
for (; xp < xend; xp++, symp += sp->cts_entsize)
{
if (sp->cts_entsize == sizeof (Elf32_Sym))
gsp = ctf_sym_to_elf64 ((Elf32_Sym *) (uintptr_t) symp, &sym);
else
gsp = (Elf64_Sym *) (uintptr_t) symp;
if (gsp->st_name < strp->cts_size)
name = (const char *) strp->cts_data + gsp->st_name;
else
name = _CTF_NULLSTR;
if (gsp->st_name == 0 || gsp->st_shndx == SHN_UNDEF
|| strcmp (name, "_START_") == 0 || strcmp (name, "_END_") == 0)
{
*xp = -1u;
continue;
}
switch (ELF64_ST_TYPE (gsp->st_info))
{
case STT_OBJECT:
if (objtoff >= hp->cth_funcoff
|| (gsp->st_shndx == SHN_EXTABS && gsp->st_value == 0))
{
*xp = -1u;
break;
}
*xp = objtoff;
objtoff += sizeof (uint32_t);
break;
case STT_FUNC:
if (funcoff >= hp->cth_typeoff)
{
*xp = -1u;
break;
}
*xp = funcoff;
info = *(uint32_t *) ((uintptr_t) fp->ctf_buf + funcoff);
vlen = LCTF_INFO_VLEN (fp, info);
/* If we encounter a zero pad at the end, just skip it. Otherwise
skip over the function and its return type (+2) and the argument
list (vlen).
*/
if (LCTF_INFO_KIND (fp, info) == CTF_K_UNKNOWN && vlen == 0)
funcoff += sizeof (uint32_t); /* Skip pad. */
else
funcoff += sizeof (uint32_t) * (vlen + 2);
break;
default:
*xp = -1u;
break;
}
}
ctf_dprintf ("loaded %lu symtab entries\n", fp->ctf_nsyms);
return 0;
}
/* Set the CTF base pointer and derive the buf pointer from it, initializing
everything in the ctf_file that depends on the base or buf pointers. */
static void
ctf_set_base (ctf_file_t *fp, const ctf_header_t *hp, void *base)
{
fp->ctf_base = base;
fp->ctf_buf = fp->ctf_base + sizeof (ctf_header_t);
fp->ctf_vars = (ctf_varent_t *) ((const char *) fp->ctf_buf +
hp->cth_varoff);
fp->ctf_nvars = (hp->cth_typeoff - hp->cth_varoff) / sizeof (ctf_varent_t);
fp->ctf_str[CTF_STRTAB_0].cts_strs = (const char *) fp->ctf_buf
+ hp->cth_stroff;
fp->ctf_str[CTF_STRTAB_0].cts_len = hp->cth_strlen;
/* If we have a parent container name and label, store the relocated
string pointers in the CTF container for easy access later. */
/* Note: before conversion, these will be set to values that will be
immediately invalidated by the conversion process, but the conversion
process will call ctf_set_base() again to fix things up. */
if (hp->cth_parlabel != 0)
fp->ctf_parlabel = ctf_strptr (fp, hp->cth_parlabel);
if (hp->cth_parname != 0)
fp->ctf_parname = ctf_strptr (fp, hp->cth_parname);
ctf_dprintf ("ctf_set_base: parent name %s (label %s)\n",
fp->ctf_parname ? fp->ctf_parname : "<NULL>",
fp->ctf_parlabel ? fp->ctf_parlabel : "<NULL>");
}
/* Free a ctf_base pointer: the pointer passed, or (if NULL) fp->ctf_base. */
static void
ctf_free_base (ctf_file_t *fp, unsigned char *ctf_base, size_t ctf_size)
{
unsigned char *base;
size_t size;
if (ctf_base)
{
base = ctf_base;
size = ctf_size;
}
else
{
base = (unsigned char *) fp->ctf_base;
size = fp->ctf_size;
}
if (base != fp->ctf_data.cts_data && base != NULL)
ctf_data_free (base, size);
}
/* Set the version of the CTF file. */
/* When this is reset, LCTF_* changes behaviour, but there is no guarantee that
the variable data list associated with each type has been upgraded: the
caller must ensure this has been done in advance. */
static void
ctf_set_version (ctf_file_t * fp, ctf_header_t * cth, int ctf_version)
{
fp->ctf_version = ctf_version;
cth->cth_version = ctf_version;
fp->ctf_fileops = &ctf_fileops[ctf_version];
}
/* Upgrade the type table to CTF_VERSION_3 (really CTF_VERSION_1_UPGRADED_3).
The upgrade is not done in-place: the ctf_base is moved. ctf_strptr() must
not be called before reallocation is complete.
Type kinds not checked here due to nonexistence in older formats:
CTF_K_SLICE. */
static int
upgrade_types (ctf_file_t *fp, ctf_header_t *cth)
{
const ctf_type_v1_t *tbuf;
const ctf_type_v1_t *tend;
unsigned char *ctf_base, *old_ctf_base = (unsigned char *) fp->ctf_base;
size_t old_ctf_size = fp->ctf_size;
ctf_type_t *t2buf;
ssize_t increase = 0, size, increment, v2increment, vbytes, v2bytes;
const ctf_type_v1_t *tp;
ctf_type_t *t2p;
ctf_header_t *new_cth;
tbuf = (ctf_type_v1_t *) (fp->ctf_buf + cth->cth_typeoff);
tend = (ctf_type_v1_t *) (fp->ctf_buf + cth->cth_stroff);
/* Much like init_types(), this is a two-pass process.
First, figure out the new type-section size needed. (It is possible,
in theory, for it to be less than the old size, but this is very
unlikely. It cannot be so small that cth_typeoff ends up of negative
size. We validate this with an assertion below.)
We must cater not only for changes in vlen and types sizes but also
for changes in 'increment', which happen because v2 places some types
into ctf_stype_t where v1 would be forced to use the larger non-stype. */
for (tp = tbuf; tp < tend;
tp = (ctf_type_v1_t *) ((uintptr_t) tp + increment + vbytes))
{
unsigned short kind = CTF_V1_INFO_KIND (tp->ctt_info);
unsigned long vlen = CTF_V1_INFO_VLEN (tp->ctt_info);
size = get_ctt_size_v1 (fp, (const ctf_type_t *) tp, NULL, &increment);
vbytes = get_vbytes_v1 (kind, size, vlen);
get_ctt_size_v2_unconverted (fp, (const ctf_type_t *) tp, NULL,
&v2increment);
v2bytes = get_vbytes_v2 (kind, size, vlen);
if ((vbytes < 0) || (size < 0))
return ECTF_CORRUPT;
increase += v2increment - increment; /* May be negative. */
increase += v2bytes - vbytes;
}
/* Allocate enough room for the new buffer, then copy everything but the
type section into place, and reset the base accordingly. Leave the
version number unchanged, so that LCTF_INFO_* still works on the
as-yet-untranslated type info. */
if ((ctf_base = ctf_data_alloc (fp->ctf_size + increase)) == NULL)
return ECTF_ZALLOC;
memcpy (ctf_base, fp->ctf_base, sizeof (ctf_header_t) + cth->cth_typeoff);
memcpy (ctf_base + sizeof (ctf_header_t) + cth->cth_stroff + increase,
fp->ctf_base + sizeof (ctf_header_t) + cth->cth_stroff,
cth->cth_strlen);
memset (ctf_base + sizeof (ctf_header_t) + cth->cth_typeoff, 0,
cth->cth_stroff - cth->cth_typeoff + increase);
/* The cth here is an automatic variable in ctf_bufopen(), and transient
(a copy maintained because at that stage the header read out of the
ctf file may be read-only). We make all modifications in the
canonical copy at ctf_base (by now, writable), then copy it back into
cth at the end. */
new_cth = (ctf_header_t *) ctf_base;
new_cth->cth_stroff += increase;
fp->ctf_size += increase;
assert (new_cth->cth_stroff >= new_cth->cth_typeoff);
ctf_set_base (fp, new_cth, ctf_base);
t2buf = (ctf_type_t *) (fp->ctf_buf + new_cth->cth_typeoff);
/* Iterate through all the types again, upgrading them.
Everything that hasn't changed can just be outright memcpy()ed.
Things that have changed need field-by-field consideration. */
for (tp = tbuf, t2p = t2buf; tp < tend;
tp = (ctf_type_v1_t *) ((uintptr_t) tp + increment + vbytes),
t2p = (ctf_type_t *) ((uintptr_t) t2p + v2increment + v2bytes))
{
unsigned short kind = CTF_V1_INFO_KIND (tp->ctt_info);
int isroot = CTF_V1_INFO_ISROOT (tp->ctt_info);
unsigned long vlen = CTF_V1_INFO_VLEN (tp->ctt_info);
ssize_t v2size;
void *vdata, *v2data;
size = get_ctt_size_v1 (fp, (const ctf_type_t *) tp, NULL, &increment);
vbytes = get_vbytes_v1 (kind, size, vlen);
t2p->ctt_name = tp->ctt_name;
t2p->ctt_info = CTF_TYPE_INFO (kind, isroot, vlen);
switch (kind)
{
case CTF_K_FUNCTION:
case CTF_K_FORWARD:
case CTF_K_TYPEDEF:
case CTF_K_POINTER:
case CTF_K_VOLATILE:
case CTF_K_CONST:
case CTF_K_RESTRICT:
t2p->ctt_type = tp->ctt_type;
break;
case CTF_K_INTEGER:
case CTF_K_FLOAT:
case CTF_K_ARRAY:
case CTF_K_STRUCT:
case CTF_K_UNION:
case CTF_K_ENUM:
case CTF_K_UNKNOWN:
if (size <= CTF_MAX_SIZE)
t2p->ctt_size = size;
else
{
t2p->ctt_lsizehi = CTF_SIZE_TO_LSIZE_HI (size);
t2p->ctt_lsizelo = CTF_SIZE_TO_LSIZE_LO (size);
}
break;
}
v2size = get_ctt_size_v2 (fp, t2p, NULL, &v2increment);
v2bytes = get_vbytes_v2 (kind, v2size, vlen);
/* Catch out-of-sync get_ctt_size_*(). The count goes wrong if
these are not identical (and having them different makes no
sense semantically). */
assert (size == v2size);
/* Now the varlen info. */
vdata = (void *) ((uintptr_t) tp + increment);
v2data = (void *) ((uintptr_t) t2p + v2increment);
switch (kind)
{
case CTF_K_ARRAY:
{
const ctf_array_v1_t *ap = (const ctf_array_v1_t *) vdata;
ctf_array_t *a2p = (ctf_array_t *) v2data;
a2p->cta_contents = ap->cta_contents;
a2p->cta_index = ap->cta_index;
a2p->cta_nelems = ap->cta_nelems;
break;
}
case CTF_K_STRUCT:
case CTF_K_UNION:
{
ctf_member_t tmp;
const ctf_member_v1_t *m1 = (const ctf_member_v1_t *) vdata;
const ctf_lmember_v1_t *lm1 = (const ctf_lmember_v1_t *) m1;
ctf_member_t *m2 = (ctf_member_t *) v2data;
ctf_lmember_t *lm2 = (ctf_lmember_t *) m2;
unsigned long i;
/* We walk all four pointers forward, but only reference the two
that are valid for the given size, to avoid quadruplicating all
the code. */
for (i = vlen; i != 0; i--, m1++, lm1++, m2++, lm2++)
{
size_t offset;
if (size < CTF_LSTRUCT_THRESH_V1)
{
offset = m1->ctm_offset;
tmp.ctm_name = m1->ctm_name;
tmp.ctm_type = m1->ctm_type;
}
else
{
offset = CTF_LMEM_OFFSET (lm1);
tmp.ctm_name = lm1->ctlm_name;
tmp.ctm_type = lm1->ctlm_type;
}
if (size < CTF_LSTRUCT_THRESH)
{
m2->ctm_name = tmp.ctm_name;
m2->ctm_type = tmp.ctm_type;
m2->ctm_offset = offset;
}
else
{
lm2->ctlm_name = tmp.ctm_name;
lm2->ctlm_type = tmp.ctm_type;
lm2->ctlm_offsethi = CTF_OFFSET_TO_LMEMHI (offset);
lm2->ctlm_offsetlo = CTF_OFFSET_TO_LMEMLO (offset);
}
}
break;
}
case CTF_K_FUNCTION:
{
unsigned long i;
unsigned short *a1 = (unsigned short *) vdata;
uint32_t *a2 = (uint32_t *) v2data;
for (i = vlen; i != 0; i--, a1++, a2++)
*a2 = *a1;
}
/* FALLTHRU */
default:
/* Catch out-of-sync get_vbytes_*(). */
assert (vbytes == v2bytes);
memcpy (v2data, vdata, vbytes);
}
}
/* Verify that the entire region was converted. If not, we are either
converting too much, or too little (leading to a buffer overrun either here
or at read time, in init_types().) */
assert ((size_t) t2p - (size_t) fp->ctf_buf == new_cth->cth_stroff);
ctf_set_version (fp, (ctf_header_t *) ctf_base, CTF_VERSION_1_UPGRADED_3);
ctf_free_base (fp, old_ctf_base, old_ctf_size);
memcpy (cth, new_cth, sizeof (ctf_header_t));
return 0;
}
/* Initialize the type ID translation table with the byte offset of each type,
and initialize the hash tables of each named type. Upgrade the type table to
the latest supported representation in the process, if needed, and if this
recension of libctf supports upgrading. */
static int
init_types (ctf_file_t *fp, ctf_header_t *cth)
{
const ctf_type_t *tbuf;
const ctf_type_t *tend;
unsigned long pop[CTF_K_MAX + 1] = { 0 };
const ctf_type_t *tp;
ctf_hash_t *hp;
uint32_t id, dst;
uint32_t *xp;
/* We determine whether the container is a child or a parent based on
the value of cth_parname. */
int child = cth->cth_parname != 0;
int nlstructs = 0, nlunions = 0;
int err;
if (_libctf_unlikely_ (fp->ctf_version == CTF_VERSION_1))
{
int err;
if ((err = upgrade_types (fp, cth)) != 0)
return err; /* Upgrade failed. */
}
tbuf = (ctf_type_t *) (fp->ctf_buf + cth->cth_typeoff);
tend = (ctf_type_t *) (fp->ctf_buf + cth->cth_stroff);
/* We make two passes through the entire type section. In this first
pass, we count the number of each type and the total number of types. */
for (tp = tbuf; tp < tend; fp->ctf_typemax++)
{
unsigned short kind = LCTF_INFO_KIND (fp, tp->ctt_info);
unsigned long vlen = LCTF_INFO_VLEN (fp, tp->ctt_info);
ssize_t size, increment, vbytes;
(void) ctf_get_ctt_size (fp, tp, &size, &increment);
vbytes = LCTF_VBYTES (fp, kind, size, vlen);
if (vbytes < 0)
return ECTF_CORRUPT;
if (kind == CTF_K_FORWARD)
{
/* For forward declarations, ctt_type is the CTF_K_* kind for the tag,
so bump that population count too. If ctt_type is unknown, treat
the tag as a struct. */
if (tp->ctt_type == CTF_K_UNKNOWN || tp->ctt_type >= CTF_K_MAX)
pop[CTF_K_STRUCT]++;
else
pop[tp->ctt_type]++;
}
tp = (ctf_type_t *) ((uintptr_t) tp + increment + vbytes);
pop[kind]++;
}
if (child)
{
ctf_dprintf ("CTF container %p is a child\n", (void *) fp);
fp->ctf_flags |= LCTF_CHILD;
}
else
ctf_dprintf ("CTF container %p is a parent\n", (void *) fp);
/* Now that we've counted up the number of each type, we can allocate
the hash tables, type translation table, and pointer table. */
if ((fp->ctf_structs = ctf_hash_create (pop[CTF_K_STRUCT], ctf_hash_string,
ctf_hash_eq_string)) == NULL)
return ENOMEM;
if ((fp->ctf_unions = ctf_hash_create (pop[CTF_K_UNION], ctf_hash_string,
ctf_hash_eq_string)) == NULL)
return ENOMEM;
if ((fp->ctf_enums = ctf_hash_create (pop[CTF_K_ENUM], ctf_hash_string,
ctf_hash_eq_string)) == NULL)
return ENOMEM;
if ((fp->ctf_names = ctf_hash_create (pop[CTF_K_INTEGER] +
pop[CTF_K_FLOAT] +
pop[CTF_K_FUNCTION] +
pop[CTF_K_TYPEDEF] +
pop[CTF_K_POINTER] +
pop[CTF_K_VOLATILE] +
pop[CTF_K_CONST] +
pop[CTF_K_RESTRICT],
ctf_hash_string,
ctf_hash_eq_string)) == NULL)
return ENOMEM;
fp->ctf_txlate = ctf_alloc (sizeof (uint32_t) * (fp->ctf_typemax + 1));
fp->ctf_ptrtab = ctf_alloc (sizeof (uint32_t) * (fp->ctf_typemax + 1));
if (fp->ctf_txlate == NULL || fp->ctf_ptrtab == NULL)
return ENOMEM; /* Memory allocation failed. */
xp = fp->ctf_txlate;
*xp++ = 0; /* Type id 0 is used as a sentinel value. */
memset (fp->ctf_txlate, 0, sizeof (uint32_t) * (fp->ctf_typemax + 1));
memset (fp->ctf_ptrtab, 0, sizeof (uint32_t) * (fp->ctf_typemax + 1));
/* In the second pass through the types, we fill in each entry of the
type and pointer tables and add names to the appropriate hashes. */
for (id = 1, tp = tbuf; tp < tend; xp++, id++)
{
unsigned short kind = LCTF_INFO_KIND (fp, tp->ctt_info);
unsigned short flag = LCTF_INFO_ISROOT (fp, tp->ctt_info);
unsigned long vlen = LCTF_INFO_VLEN (fp, tp->ctt_info);
ssize_t size, increment, vbytes;
const char *name;
(void) ctf_get_ctt_size (fp, tp, &size, &increment);
name = ctf_strptr (fp, tp->ctt_name);
vbytes = LCTF_VBYTES (fp, kind, size, vlen);
switch (kind)
{
case CTF_K_INTEGER:
case CTF_K_FLOAT:
/* Names are reused by bit-fields, which are differentiated by their
encodings, and so typically we'd record only the first instance of
a given intrinsic. However, we replace an existing type with a
root-visible version so that we can be sure to find it when
checking for conflicting definitions in ctf_add_type(). */
if (((ctf_hash_lookup_type (fp->ctf_names, fp, name)) == 0)
|| (flag & CTF_ADD_ROOT))
{
err = ctf_hash_define_type (fp->ctf_names, fp,
LCTF_INDEX_TO_TYPE (fp, id, child),
tp->ctt_name);
if (err != 0 && err != ECTF_STRTAB)
return err;
}
break;
/* These kinds have no name, so do not need interning into any
hashtables. */
case CTF_K_ARRAY:
case CTF_K_SLICE:
break;
case CTF_K_FUNCTION:
err = ctf_hash_insert_type (fp->ctf_names, fp,
LCTF_INDEX_TO_TYPE (fp, id, child),
tp->ctt_name);
if (err != 0 && err != ECTF_STRTAB)
return err;
break;
case CTF_K_STRUCT:
err = ctf_hash_define_type (fp->ctf_structs, fp,
LCTF_INDEX_TO_TYPE (fp, id, child),
tp->ctt_name);
if (err != 0 && err != ECTF_STRTAB)
return err;
if (size >= CTF_LSTRUCT_THRESH)
nlstructs++;
break;
case CTF_K_UNION:
err = ctf_hash_define_type (fp->ctf_unions, fp,
LCTF_INDEX_TO_TYPE (fp, id, child),
tp->ctt_name);
if (err != 0 && err != ECTF_STRTAB)
return err;
if (size >= CTF_LSTRUCT_THRESH)
nlunions++;
break;
case CTF_K_ENUM:
err = ctf_hash_define_type (fp->ctf_enums, fp,
LCTF_INDEX_TO_TYPE (fp, id, child),
tp->ctt_name);
if (err != 0 && err != ECTF_STRTAB)
return err;
break;
case CTF_K_TYPEDEF:
err = ctf_hash_insert_type (fp->ctf_names, fp,
LCTF_INDEX_TO_TYPE (fp, id, child),
tp->ctt_name);
if (err != 0 && err != ECTF_STRTAB)
return err;
break;
case CTF_K_FORWARD:
/* Only insert forward tags into the given hash if the type or tag
name is not already present. */
switch (tp->ctt_type)
{
case CTF_K_STRUCT:
hp = fp->ctf_structs;
break;
case CTF_K_UNION:
hp = fp->ctf_unions;
break;
case CTF_K_ENUM:
hp = fp->ctf_enums;
break;
default:
hp = fp->ctf_structs;
}
if (ctf_hash_lookup_type (hp, fp, name) == 0)
{
err = ctf_hash_insert_type (hp, fp,
LCTF_INDEX_TO_TYPE (fp, id, child),
tp->ctt_name);
if (err != 0 && err != ECTF_STRTAB)
return err;
}
break;
case CTF_K_POINTER:
/* If the type referenced by the pointer is in this CTF container,
then store the index of the pointer type in
fp->ctf_ptrtab[ index of referenced type ]. */
if (LCTF_TYPE_ISCHILD (fp, tp->ctt_type) == child
&& LCTF_TYPE_TO_INDEX (fp, tp->ctt_type) <= fp->ctf_typemax)
fp->ctf_ptrtab[LCTF_TYPE_TO_INDEX (fp, tp->ctt_type)] = id;
/*FALLTHRU*/
case CTF_K_VOLATILE:
case CTF_K_CONST:
case CTF_K_RESTRICT:
err = ctf_hash_insert_type (fp->ctf_names, fp,
LCTF_INDEX_TO_TYPE (fp, id, child),
tp->ctt_name);
if (err != 0 && err != ECTF_STRTAB)
return err;
break;
}
*xp = (uint32_t) ((uintptr_t) tp - (uintptr_t) fp->ctf_buf);
tp = (ctf_type_t *) ((uintptr_t) tp + increment + vbytes);
}
ctf_dprintf ("%lu total types processed\n", fp->ctf_typemax);
ctf_dprintf ("%u enum names hashed\n", ctf_hash_size (fp->ctf_enums));
ctf_dprintf ("%u struct names hashed (%d long)\n",
ctf_hash_size (fp->ctf_structs), nlstructs);
ctf_dprintf ("%u union names hashed (%d long)\n",
ctf_hash_size (fp->ctf_unions), nlunions);
ctf_dprintf ("%u base type names hashed\n", ctf_hash_size (fp->ctf_names));
/* Make an additional pass through the pointer table to find pointers that
point to anonymous typedef nodes. If we find one, modify the pointer table
so that the pointer is also known to point to the node that is referenced
by the anonymous typedef node. */
for (id = 1; id <= fp->ctf_typemax; id++)
{
if ((dst = fp->ctf_ptrtab[id]) != 0)
{
tp = LCTF_INDEX_TO_TYPEPTR (fp, id);
if (LCTF_INFO_KIND (fp, tp->ctt_info) == CTF_K_TYPEDEF &&
strcmp (ctf_strptr (fp, tp->ctt_name), "") == 0 &&
LCTF_TYPE_ISCHILD (fp, tp->ctt_type) == child &&
LCTF_TYPE_TO_INDEX (fp, tp->ctt_type) <= fp->ctf_typemax)
fp->ctf_ptrtab[LCTF_TYPE_TO_INDEX (fp, tp->ctt_type)] = dst;
}
}
return 0;
}
/* Endianness-flipping routines.
We flip everything, mindlessly, even 1-byte entities, so that future
expansions do not require changes to this code. */
/* < C11? define away static assertions. */
#if !defined (__STDC_VERSION__) || __STDC_VERSION__ < 201112L
#define _Static_assert(cond, err)
#endif
/* Swap the endianness of something. */
#define swap_thing(x) \
do { \
_Static_assert (sizeof (x) == 1 || (sizeof (x) % 2 == 0 \
&& sizeof (x) <= 8), \
"Invalid size, update endianness code"); \
switch (sizeof (x)) { \
case 2: x = bswap_16 (x); break; \
case 4: x = bswap_32 (x); break; \
case 8: x = bswap_64 (x); break; \
case 1: /* Nothing needs doing */ \
break; \
} \
} while (0);
/* Flip the endianness of the CTF header. */
static void
flip_header (ctf_header_t *cth)
{
swap_thing (cth->cth_preamble.ctp_magic);
swap_thing (cth->cth_preamble.ctp_version);
swap_thing (cth->cth_preamble.ctp_flags);
swap_thing (cth->cth_parlabel);
swap_thing (cth->cth_parname);
swap_thing (cth->cth_objtoff);
swap_thing (cth->cth_funcoff);
swap_thing (cth->cth_varoff);
swap_thing (cth->cth_typeoff);
swap_thing (cth->cth_stroff);
swap_thing (cth->cth_strlen);
}
/* Flip the endianness of the label section, an array of ctf_lblent_t. */
static void
flip_lbls (void *start, size_t len)
{
ctf_lblent_t *lbl = start;
for (ssize_t i = len / sizeof (struct ctf_lblent); i > 0; lbl++, i--)
{
swap_thing (lbl->ctl_label);
swap_thing (lbl->ctl_type);
}
}
/* Flip the endianness of the data-object or function sections, an array of
uint32_t. (The function section has more internal structure, but that
structure is an array of uint32_t, so can be treated as one big array for
byte-swapping.) */
static void
flip_objts (void *start, size_t len)
{
uint32_t *obj = start;
for (ssize_t i = len / sizeof (uint32_t); i > 0; obj++, i--)
swap_thing (*obj);
}
/* Flip the endianness of the variable section, an array of ctf_varent_t. */
static void
flip_vars (void *start, size_t len)
{
ctf_varent_t *var = start;
for (ssize_t i = len / sizeof (struct ctf_varent); i > 0; var++, i--)
{
swap_thing (var->ctv_name);
swap_thing (var->ctv_type);
}
}
/* Flip the endianness of the type section, a tagged array of ctf_type or
ctf_stype followed by variable data. */
static int
flip_types (void *start, size_t len)
{
ctf_type_t *t = start;
while ((uintptr_t) t < ((uintptr_t) start) + len)
{
swap_thing (t->ctt_name);
swap_thing (t->ctt_info);
swap_thing (t->ctt_size);
uint32_t kind = CTF_V2_INFO_KIND (t->ctt_info);
size_t size = t->ctt_size;
uint32_t vlen = CTF_V2_INFO_VLEN (t->ctt_info);
size_t vbytes = get_vbytes_v2 (kind, size, vlen);
if (_libctf_unlikely_ (size == CTF_LSIZE_SENT))
{
swap_thing (t->ctt_lsizehi);
swap_thing (t->ctt_lsizelo);
size = CTF_TYPE_LSIZE (t);
t = (ctf_type_t *) ((uintptr_t) t + sizeof (ctf_type_t));
}
else
t = (ctf_type_t *) ((uintptr_t) t + sizeof (ctf_stype_t));
switch (kind)
{
case CTF_K_FORWARD:
case CTF_K_UNKNOWN:
case CTF_K_POINTER:
case CTF_K_TYPEDEF:
case CTF_K_VOLATILE:
case CTF_K_CONST:
case CTF_K_RESTRICT:
/* These types have no vlen data to swap. */
assert (vbytes == 0);
break;
case CTF_K_INTEGER:
case CTF_K_FLOAT:
{
/* These types have a single uint32_t. */
uint32_t *item = (uint32_t *) t;
swap_thing (*item);
break;
}
case CTF_K_FUNCTION:
{
/* This type has a bunch of uint32_ts. */
uint32_t *item = (uint32_t *) t;
for (ssize_t i = vlen; i > 0; item++, i--)
swap_thing (*item);
break;
}
case CTF_K_ARRAY:
{
/* This has a single ctf_array_t. */
ctf_array_t *a = (ctf_array_t *) t;
assert (vbytes == sizeof (ctf_array_t));
swap_thing (a->cta_contents);
swap_thing (a->cta_index);
swap_thing (a->cta_nelems);
break;
}
case CTF_K_SLICE:
{
/* This has a single ctf_slice_t. */
ctf_slice_t *s = (ctf_slice_t *) t;
assert (vbytes == sizeof (ctf_slice_t));
swap_thing (s->cts_type);
swap_thing (s->cts_offset);
swap_thing (s->cts_bits);
break;
}
case CTF_K_STRUCT:
case CTF_K_UNION:
{
/* This has an array of ctf_member or ctf_lmember, depending on
size. We could consider it to be a simple array of uint32_t,
but for safety's sake in case these structures ever acquire
non-uint32_t members, do it member by member. */
if (_libctf_unlikely_ (size >= CTF_LSTRUCT_THRESH))
{
ctf_lmember_t *lm = (ctf_lmember_t *) t;
for (ssize_t i = vlen; i > 0; i--, lm++)
{
swap_thing (lm->ctlm_name);
swap_thing (lm->ctlm_offsethi);
swap_thing (lm->ctlm_type);
swap_thing (lm->ctlm_offsetlo);
}
}
else
{
ctf_member_t *m = (ctf_member_t *) t;
for (ssize_t i = vlen; i > 0; i--, m++)
{
swap_thing (m->ctm_name);
swap_thing (m->ctm_offset);
swap_thing (m->ctm_type);
}
}
break;
}
case CTF_K_ENUM:
{
/* This has an array of ctf_enum_t. */
ctf_enum_t *item = (ctf_enum_t *) t;
for (ssize_t i = vlen; i > 0; item++, i--)
{
swap_thing (item->cte_name);
swap_thing (item->cte_value);
}
break;
}
default:
ctf_dprintf ("unhandled CTF kind in endianness conversion -- %x\n",
kind);
return ECTF_CORRUPT;
}
t = (ctf_type_t *) ((uintptr_t) t + vbytes);
}
return 0;
}
/* Flip the endianness of BASE, given the offsets in the (already endian-
converted) CTH.
All of this stuff happens before the header is fully initialized, so the
LCTF_*() macros cannot be used yet. Since we do not try to endian-convert v1
data, this is no real loss. */
static int
flip_ctf (ctf_header_t *cth, unsigned char *base)
{
base += sizeof (ctf_header_t);
flip_lbls (base + cth->cth_lbloff, cth->cth_objtoff - cth->cth_lbloff);
flip_objts (base + cth->cth_objtoff, cth->cth_funcoff - cth->cth_objtoff);
flip_objts (base + cth->cth_funcoff, cth->cth_varoff - cth->cth_funcoff);
flip_vars (base + cth->cth_varoff, cth->cth_typeoff - cth->cth_varoff);
return flip_types (base + cth->cth_typeoff, cth->cth_stroff - cth->cth_typeoff);
}
/* Open a CTF file, mocking up a suitable ctf_sect. */
ctf_file_t *ctf_simple_open (const char *ctfsect, size_t ctfsect_size,
const char *symsect, size_t symsect_size,
size_t symsect_entsize,
const char *strsect, size_t strsect_size,
int *errp)
{
ctf_sect_t skeleton;
ctf_sect_t ctf_sect, sym_sect, str_sect;
ctf_sect_t *ctfsectp = NULL;
ctf_sect_t *symsectp = NULL;
ctf_sect_t *strsectp = NULL;
skeleton.cts_name = _CTF_SECTION;
skeleton.cts_type = SHT_PROGBITS;
skeleton.cts_flags = 0;
skeleton.cts_entsize = 1;
skeleton.cts_offset = 0;
if (ctfsect)
{
memcpy (&ctf_sect, &skeleton, sizeof (struct ctf_sect));
ctf_sect.cts_data = ctfsect;
ctf_sect.cts_size = ctfsect_size;
ctfsectp = &ctf_sect;
}
if (symsect)
{
memcpy (&sym_sect, &skeleton, sizeof (struct ctf_sect));
sym_sect.cts_data = symsect;
sym_sect.cts_size = symsect_size;
sym_sect.cts_entsize = symsect_entsize;
symsectp = &sym_sect;
}
if (strsect)
{
memcpy (&str_sect, &skeleton, sizeof (struct ctf_sect));
str_sect.cts_data = strsect;
str_sect.cts_size = strsect_size;
strsectp = &str_sect;
}
return ctf_bufopen (ctfsectp, symsectp, strsectp, errp);
}
/* Decode the specified CTF buffer and optional symbol table, and create a new
CTF container representing the symbolic debugging information. This code can
be used directly by the debugger, or it can be used as the engine for
ctf_fdopen() or ctf_open(), below. */
ctf_file_t *
ctf_bufopen (const ctf_sect_t *ctfsect, const ctf_sect_t *symsect,
const ctf_sect_t *strsect, int *errp)
{
const ctf_preamble_t *pp;
ctf_header_t hp;
ctf_file_t *fp;
void *buf, *base;
size_t size, hdrsz;
int foreign_endian = 0;
int err;
libctf_init_debug();
if (ctfsect == NULL || ((symsect == NULL) != (strsect == NULL)))
return (ctf_set_open_errno (errp, EINVAL));
if (symsect != NULL && symsect->cts_entsize != sizeof (Elf32_Sym) &&
symsect->cts_entsize != sizeof (Elf64_Sym))
return (ctf_set_open_errno (errp, ECTF_SYMTAB));
if (symsect != NULL && symsect->cts_data == NULL)
return (ctf_set_open_errno (errp, ECTF_SYMBAD));
if (strsect != NULL && strsect->cts_data == NULL)
return (ctf_set_open_errno (errp, ECTF_STRBAD));
if (ctfsect->cts_size < sizeof (ctf_preamble_t))
return (ctf_set_open_errno (errp, ECTF_NOCTFBUF));
pp = (const ctf_preamble_t *) ctfsect->cts_data;
ctf_dprintf ("ctf_bufopen: magic=0x%x version=%u\n",
pp->ctp_magic, pp->ctp_version);
/* Validate each part of the CTF header.
First, we validate the preamble (common to all versions). At that point,
we know the endianness and specific header version, and can validate the
version-specific parts including section offsets and alignments.
We specifically do not support foreign-endian old versions. */
if (_libctf_unlikely_ (pp->ctp_magic != CTF_MAGIC))
{
if (pp->ctp_magic == bswap_16 (CTF_MAGIC))
{
if (pp->ctp_version != CTF_VERSION_3)
return (ctf_set_open_errno (errp, ECTF_CTFVERS));
foreign_endian = 1;
}
else
return (ctf_set_open_errno (errp, ECTF_NOCTFBUF));
}
if (_libctf_unlikely_ ((pp->ctp_version < CTF_VERSION_1)
|| (pp->ctp_version > CTF_VERSION_3)))
return (ctf_set_open_errno (errp, ECTF_CTFVERS));
if ((symsect != NULL) && (pp->ctp_version < CTF_VERSION_2))
{
/* The symtab can contain function entries which contain embedded ctf
info. We do not support dynamically upgrading such entries (none
should exist in any case, since dwarf2ctf does not create them). */
ctf_dprintf ("ctf_bufopen: CTF version %d symsect not "
"supported\n", pp->ctp_version);
return (ctf_set_open_errno (errp, ECTF_NOTSUP));
}
if (ctfsect->cts_size < sizeof (ctf_header_t))
return (ctf_set_open_errno (errp, ECTF_NOCTFBUF));
memcpy (&hp, ctfsect->cts_data, sizeof (hp));
if (foreign_endian)
flip_header (&hp);
hdrsz = sizeof (ctf_header_t);
size = hp.cth_stroff + hp.cth_strlen;
ctf_dprintf ("ctf_bufopen: uncompressed size=%lu\n", (unsigned long) size);
if (hp.cth_lbloff > size || hp.cth_objtoff > size
|| hp.cth_funcoff > size || hp.cth_typeoff > size || hp.cth_stroff > size)
return (ctf_set_open_errno (errp, ECTF_CORRUPT));
if (hp.cth_lbloff > hp.cth_objtoff
|| hp.cth_objtoff > hp.cth_funcoff
|| hp.cth_funcoff > hp.cth_typeoff
|| hp.cth_funcoff > hp.cth_varoff
|| hp.cth_varoff > hp.cth_typeoff || hp.cth_typeoff > hp.cth_stroff)
return (ctf_set_open_errno (errp, ECTF_CORRUPT));
if ((hp.cth_lbloff & 3) || (hp.cth_objtoff & 1)
|| (hp.cth_funcoff & 1) || (hp.cth_varoff & 3) || (hp.cth_typeoff & 3))
return (ctf_set_open_errno (errp, ECTF_CORRUPT));
/* Once everything is determined to be valid, attempt to decompress the CTF
data buffer if it is compressed, or copy it into new storage if it is not
compressed but needs endian-flipping. Otherwise we just put the data
section's buffer pointer into ctf_buf, below. */
/* Note: if this is a v1 buffer, it will be reallocated and expanded by
init_types(). */
if (hp.cth_flags & CTF_F_COMPRESS)
{
size_t srclen, dstlen;
const void *src;
int rc = Z_OK;
if ((base = ctf_data_alloc (size + hdrsz)) == NULL)
return (ctf_set_open_errno (errp, ECTF_ZALLOC));
memcpy (base, ctfsect->cts_data, hdrsz);
((ctf_preamble_t *) base)->ctp_flags &= ~CTF_F_COMPRESS;
buf = (unsigned char *) base + hdrsz;
src = (unsigned char *) ctfsect->cts_data + hdrsz;
srclen = ctfsect->cts_size - hdrsz;
dstlen = size;
if ((rc = uncompress (buf, &dstlen, src, srclen)) != Z_OK)
{
ctf_dprintf ("zlib inflate err: %s\n", zError (rc));
ctf_data_free (base, size + hdrsz);
return (ctf_set_open_errno (errp, ECTF_DECOMPRESS));
}
if (dstlen != size)
{
ctf_dprintf ("zlib inflate short -- got %lu of %lu "
"bytes\n", (unsigned long) dstlen, (unsigned long) size);
ctf_data_free (base, size + hdrsz);
return (ctf_set_open_errno (errp, ECTF_CORRUPT));
}
}
else if (foreign_endian)
{
if ((base = ctf_data_alloc (size + hdrsz)) == NULL)
return (ctf_set_open_errno (errp, ECTF_ZALLOC));
}
else
{
base = (void *) ctfsect->cts_data;
buf = (unsigned char *) base + hdrsz;
}
/* Once we have uncompressed and validated the CTF data buffer, we can
proceed with allocating a ctf_file_t and initializing it.
Nothing that depends on buf or base should be set directly in this function
before the init_types() call, because it may be reallocated during
transparent upgrade if this recension of libctf is so configured: see
ctf_set_base() and ctf_realloc_base(). */
if ((fp = ctf_alloc (sizeof (ctf_file_t))) == NULL)
return (ctf_set_open_errno (errp, ENOMEM));
memset (fp, 0, sizeof (ctf_file_t));
ctf_set_version (fp, &hp, hp.cth_version);
if (_libctf_unlikely_ (hp.cth_version < CTF_VERSION_2))
fp->ctf_parmax = CTF_MAX_PTYPE_V1;
else
fp->ctf_parmax = CTF_MAX_PTYPE;
memcpy (&fp->ctf_data, ctfsect, sizeof (ctf_sect_t));
if (symsect != NULL)
{
memcpy (&fp->ctf_symtab, symsect, sizeof (ctf_sect_t));
memcpy (&fp->ctf_strtab, strsect, sizeof (ctf_sect_t));
}
if (fp->ctf_data.cts_name != NULL)
fp->ctf_data.cts_name = ctf_strdup (fp->ctf_data.cts_name);
if (fp->ctf_symtab.cts_name != NULL)
fp->ctf_symtab.cts_name = ctf_strdup (fp->ctf_symtab.cts_name);
if (fp->ctf_strtab.cts_name != NULL)
fp->ctf_strtab.cts_name = ctf_strdup (fp->ctf_strtab.cts_name);
if (fp->ctf_data.cts_name == NULL)
fp->ctf_data.cts_name = _CTF_NULLSTR;
if (fp->ctf_symtab.cts_name == NULL)
fp->ctf_symtab.cts_name = _CTF_NULLSTR;
if (fp->ctf_strtab.cts_name == NULL)
fp->ctf_strtab.cts_name = _CTF_NULLSTR;
if (strsect != NULL)
{
fp->ctf_str[CTF_STRTAB_1].cts_strs = strsect->cts_data;
fp->ctf_str[CTF_STRTAB_1].cts_len = strsect->cts_size;
}
if (foreign_endian &&
(err = flip_ctf (&hp, base)) != 0)
{
/* We can be certain that flip_ctf() will have endian-flipped everything
other than the types table when we return. In particular the header
is fine, so set it, to allow freeing to use the usual code path. */
(void) ctf_set_open_errno (errp, err);
ctf_set_base (fp, &hp, base);
goto bad;
}
ctf_set_base (fp, &hp, base);
fp->ctf_size = size + hdrsz;
if ((err = init_types (fp, &hp)) != 0)
{
(void) ctf_set_open_errno (errp, err);
goto bad;
}
/* The ctf region may have been reallocated by init_types(), but now
that is done, it will not move again, so we can protect it, as long
as it didn't come from the ctfsect, which might have been allocated
with malloc(). */
if (fp->ctf_base != (void *) ctfsect->cts_data)
ctf_data_protect ((void *) fp->ctf_base, fp->ctf_size);
/* If we have a symbol table section, allocate and initialize
the symtab translation table, pointed to by ctf_sxlate. */
if (symsect != NULL)
{
fp->ctf_nsyms = symsect->cts_size / symsect->cts_entsize;
fp->ctf_sxlate = ctf_alloc (fp->ctf_nsyms * sizeof (uint32_t));
if (fp->ctf_sxlate == NULL)
{
(void) ctf_set_open_errno (errp, ENOMEM);
goto bad;
}
if ((err = init_symtab (fp, &hp, symsect, strsect)) != 0)
{
(void) ctf_set_open_errno (errp, err);
goto bad;
}
}
/* Initialize the ctf_lookup_by_name top-level dictionary. We keep an
array of type name prefixes and the corresponding ctf_hash to use.
NOTE: This code must be kept in sync with the code in ctf_update(). */
fp->ctf_lookups[0].ctl_prefix = "struct";
fp->ctf_lookups[0].ctl_len = strlen (fp->ctf_lookups[0].ctl_prefix);
fp->ctf_lookups[0].ctl_hash = fp->ctf_structs;
fp->ctf_lookups[1].ctl_prefix = "union";
fp->ctf_lookups[1].ctl_len = strlen (fp->ctf_lookups[1].ctl_prefix);
fp->ctf_lookups[1].ctl_hash = fp->ctf_unions;
fp->ctf_lookups[2].ctl_prefix = "enum";
fp->ctf_lookups[2].ctl_len = strlen (fp->ctf_lookups[2].ctl_prefix);
fp->ctf_lookups[2].ctl_hash = fp->ctf_enums;
fp->ctf_lookups[3].ctl_prefix = _CTF_NULLSTR;
fp->ctf_lookups[3].ctl_len = strlen (fp->ctf_lookups[3].ctl_prefix);
fp->ctf_lookups[3].ctl_hash = fp->ctf_names;
fp->ctf_lookups[4].ctl_prefix = NULL;
fp->ctf_lookups[4].ctl_len = 0;
fp->ctf_lookups[4].ctl_hash = NULL;
if (symsect != NULL)
{
if (symsect->cts_entsize == sizeof (Elf64_Sym))
(void) ctf_setmodel (fp, CTF_MODEL_LP64);
else
(void) ctf_setmodel (fp, CTF_MODEL_ILP32);
}
else
(void) ctf_setmodel (fp, CTF_MODEL_NATIVE);
fp->ctf_refcnt = 1;
return fp;
bad:
ctf_file_close (fp);
return NULL;
}
/* Close the specified CTF container and free associated data structures. Note
that ctf_file_close() is a reference counted operation: if the specified file
is the parent of other active containers, its reference count will be greater
than one and it will be freed later when no active children exist. */
void
ctf_file_close (ctf_file_t *fp)
{
ctf_dtdef_t *dtd, *ntd;
ctf_dvdef_t *dvd, *nvd;
if (fp == NULL)
return; /* Allow ctf_file_close(NULL) to simplify caller code. */
ctf_dprintf ("ctf_file_close(%p) refcnt=%u\n", (void *) fp, fp->ctf_refcnt);
if (fp->ctf_refcnt > 1)
{
fp->ctf_refcnt--;
return;
}
if (fp->ctf_dynparname != NULL)
ctf_free (fp->ctf_dynparname);
if (fp->ctf_parent != NULL)
ctf_file_close (fp->ctf_parent);
for (dtd = ctf_list_next (&fp->ctf_dtdefs); dtd != NULL; dtd = ntd)
{
ntd = ctf_list_next (dtd);
ctf_dtd_delete (fp, dtd);
}
ctf_dynhash_destroy (fp->ctf_dthash);
ctf_dynhash_destroy (fp->ctf_dtbyname);
for (dvd = ctf_list_next (&fp->ctf_dvdefs); dvd != NULL; dvd = nvd)
{
nvd = ctf_list_next (dvd);
ctf_dvd_delete (fp, dvd);
}
ctf_dynhash_destroy (fp->ctf_dvhash);
ctf_free (fp->ctf_tmp_typeslice);
if (fp->ctf_data.cts_name != _CTF_NULLSTR &&
fp->ctf_data.cts_name != NULL)
ctf_free ((char *) fp->ctf_data.cts_name);
if (fp->ctf_symtab.cts_name != _CTF_NULLSTR &&
fp->ctf_symtab.cts_name != NULL)
ctf_free ((char *) fp->ctf_symtab.cts_name);
if (fp->ctf_strtab.cts_name != _CTF_NULLSTR &&
fp->ctf_strtab.cts_name != NULL)
ctf_free ((char *) fp->ctf_strtab.cts_name);
else if (fp->ctf_data_mmapped)
ctf_munmap (fp->ctf_data_mmapped, fp->ctf_data_mmapped_len);
ctf_free_base (fp, NULL, 0);
if (fp->ctf_sxlate != NULL)
ctf_free (fp->ctf_sxlate);
if (fp->ctf_txlate != NULL)
ctf_free (fp->ctf_txlate);
if (fp->ctf_ptrtab != NULL)
ctf_free (fp->ctf_ptrtab);
ctf_hash_destroy (fp->ctf_structs);
ctf_hash_destroy (fp->ctf_unions);
ctf_hash_destroy (fp->ctf_enums);
ctf_hash_destroy (fp->ctf_names);
ctf_free (fp);
}
/* Get the CTF archive from which this ctf_file_t is derived. */
ctf_archive_t *
ctf_get_arc (const ctf_file_t *fp)
{
return fp->ctf_archive;
}
/* Return the ctfsect out of the core ctf_impl. Useful for freeing the
ctfsect's data * after ctf_file_close(), which is why we return the actual
structure, not a pointer to it, since that is likely to become a pointer to
freed data before the return value is used under the expected use case of
ctf_getsect()/ ctf_file_close()/free(). */
extern ctf_sect_t
ctf_getdatasect (const ctf_file_t *fp)
{
return fp->ctf_data;
}
/* Return the CTF handle for the parent CTF container, if one exists.
Otherwise return NULL to indicate this container has no imported parent. */
ctf_file_t *
ctf_parent_file (ctf_file_t *fp)
{
return fp->ctf_parent;
}
/* Return the name of the parent CTF container, if one exists. Otherwise
return NULL to indicate this container is a root container. */
const char *
ctf_parent_name (ctf_file_t *fp)
{
return fp->ctf_parname;
}
/* Set the parent name. It is an error to call this routine without calling
ctf_import() at some point. */
void
ctf_parent_name_set (ctf_file_t *fp, const char *name)
{
if (fp->ctf_dynparname != NULL)
ctf_free (fp->ctf_dynparname);
fp->ctf_dynparname = ctf_strdup (name);
fp->ctf_parname = fp->ctf_dynparname;
}
/* Import the types from the specified parent container by storing a pointer
to it in ctf_parent and incrementing its reference count. Only one parent
is allowed: if a parent already exists, it is replaced by the new parent. */
int
ctf_import (ctf_file_t *fp, ctf_file_t *pfp)
{
if (fp == NULL || fp == pfp || (pfp != NULL && pfp->ctf_refcnt == 0))
return (ctf_set_errno (fp, EINVAL));
if (pfp != NULL && pfp->ctf_dmodel != fp->ctf_dmodel)
return (ctf_set_errno (fp, ECTF_DMODEL));
if (fp->ctf_parent != NULL)
ctf_file_close (fp->ctf_parent);
if (pfp != NULL)
{
fp->ctf_flags |= LCTF_CHILD;
pfp->ctf_refcnt++;
if (fp->ctf_parname == NULL)
ctf_parent_name_set (fp, "PARENT");
}
fp->ctf_parent = pfp;
return 0;
}
/* Set the data model constant for the CTF container. */
int
ctf_setmodel (ctf_file_t *fp, int model)
{
const ctf_dmodel_t *dp;
for (dp = _libctf_models; dp->ctd_name != NULL; dp++)
{
if (dp->ctd_code == model)
{
fp->ctf_dmodel = dp;
return 0;
}
}
return (ctf_set_errno (fp, EINVAL));
}
/* Return the data model constant for the CTF container. */
int
ctf_getmodel (ctf_file_t *fp)
{
return fp->ctf_dmodel->ctd_code;
}
void
ctf_setspecific (ctf_file_t *fp, void *data)
{
fp->ctf_specific = data;
}
void *
ctf_getspecific (ctf_file_t *fp)
{
return fp->ctf_specific;
}
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