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64b65a0a34347c21d30fa44ada3dfcf646a6423f
binutils-gdb/libctf/ctf-lookup.c
Nick Alcock 64b65a0a34 libctf: types: struct/union member querying and iteration 
This commit revises ctf_member_next, ctf_member_iter, ctf_member_count, and
ctf_member_info for the new CTFv4 world.  This also pulls in a bunch of
infrastructure used by most of the type querying functions, and fundamental
changes to the way DTD records are represented in libctf (ctf-create not yet
adjusted).  Other type querying functions affected by changes in struct
representation are also changed.

There are some API changes here: new bit-width fields in ctf_member_f,
ctf_membinfo_t and ctf_member_next, and a fix to the type of the offset in
ctf_member_f, ctf_membinfo_t and and ctf_member_count.  (ctf_member_next got
the offset type right already.)

ctf_member_f also gets a new ctf_dict_t arg so that you can actually use
the member type it passes in without having to package up and pass in the
dict type yourself (a frequent need).  This change is later echoed in most
of the rest of the *_f typedefs.

 typedef struct ctf_membinfo
 {
   ctf_id_t ctm_type;		/* Type of struct or union member.  */
-  unsigned long ctm_offset;	/* Offset of member in bits.  */
+  size_t ctm_offset;		/* Offset of member in bits.  */
+  int ctm_bit_width;		/* Width of member in bits: -1: not bitfield */
 } ctf_membinfo_t;

-typedef int ctf_member_f (const char *name, ctf_id_t membtype,
-			  unsigned long offset, void *arg);
+typedef int ctf_member_f (ctf_dict_t *, const char *name, ctf_id_t membtype,
+			  size_t offset, int bit_width, void *arg);

 extern ssize_t ctf_member_next (ctf_dict_t *, ctf_id_t, ctf_next_t **,
 				const char **name, ctf_id_t *membtype,
-				int flags);
+				int *bit_width, int flags);

-int ctf_member_count (ctf_dict_t *, ctf_id_t);
+ssize_t ctf_member_count (ctf_dict_t *, ctf_id_t);

The DTD changes are that where before the ctf_dtdef_t had a dtd_data which
was the ctf_type_t type node for a type, and a separate dtd_vlen which was
the vlen buffer which (in the final serialized representation) would
directly follow that type, now it has one single buffer, dtd_buf, which
consists of a stream of one or more ctf_type_t nodes, followed by a vlen,
as it will appear in the final serialized form.  This buffer has internal
pointers into it: dtd_data is a pointer to the last ctf_type_t in the stream
(the true type node, after all prefixes), and dtd_vlen is a pointer to the
vlen (precisely one ctf_type_t after the dtd_data).  This representation is
nice because it means there is even less distinction between a dynamic type
added by ctf_add_*() and a static one read directly out of a dict: you can
traverse the entire type without caring where it came from, simplifying
most of the type querying functions.

(There are a few more things in there which will be useful mostly when
adding new types: their uses will be seen later.)

Two new nontrivial functions exist (one of which is annoyingly tangled up in
the diff, sorry about that): ctf_find_prefix, which hunts down a given
prefix (if it exists) among the possibly many that may exist on a type (so
you can ask it to find the CTF_K_BIG prefix for a type if it exists, and
it'll return you a pointer to its ctf_type_t record), and ctf_vlen, which
you hand a type ID and its ctf_type_t *, and it gives you back a pointer to
its vlen and tells you how long it is.  (This is one of only two places left
in ctf-types.c which cares whether a type is dynamic or not.  The other has
yet to be added).  Almost every function in ctf-types.c will end up calling
ctf_lookup_by_id and ctf_vlen in turn.

ctf_next_t has changed significantly: the ctn_type member is split in two so
that we can tell whether a given iterator works using types or indexes, and
we gain the ability to iterate over enum64s, DTDs themselves, and datasecs
(most of this will only be used in later commits).

The old internal function ctf_struct_member, which handled the distinction
between ctf_member_t and ctf_lmember_t, is gone.  Instead we have new code
that handles the different representation of bitfield versus non-bitfield
structs and unions, and more code to handle the different representation of
CTF_K_BIG structs and unions (their offsets are the distance from the last
offset, rather than the distance from the start of the structure).
2025-04-25 18:07:42 +01:00

1423 lines
39 KiB
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/* Symbol, variable and name lookup.
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 <elf.h>
#include <string.h>
#include <assert.h>
/* Grow the pptrtab so that it is at least NEW_LEN long. */
static int
grow_pptrtab (ctf_dict_t *fp, size_t new_len)
{
uint32_t *new_pptrtab;
if ((new_pptrtab = realloc (fp->ctf_pptrtab, sizeof (uint32_t)
* new_len)) == NULL)
return (ctf_set_errno (fp, ENOMEM));
fp->ctf_pptrtab = new_pptrtab;
memset (fp->ctf_pptrtab + fp->ctf_pptrtab_len, 0,
sizeof (uint32_t) * (new_len - fp->ctf_pptrtab_len));
fp->ctf_pptrtab_len = new_len;
return 0;
}
/* Update entries in the pptrtab that relate to types newly added in the
child. */
static int
refresh_pptrtab (ctf_dict_t *fp, ctf_dict_t *pfp)
{
uint32_t i;
for (i = fp->ctf_pptrtab_typemax; i <= fp->ctf_typemax; i++)
{
ctf_id_t type = ctf_index_to_type (fp, i);
ctf_id_t reffed_type;
if (ctf_type_kind (fp, type) != CTF_K_POINTER)
continue;
reffed_type = ctf_type_reference (fp, type);
if (ctf_type_isparent (fp, reffed_type))
{
uint32_t idx = ctf_type_to_index (pfp, reffed_type);
/* Guard against references to invalid types. No need to consider
the CTF dict corrupt in this case: this pointer just can't be a
pointer to any type we know about. */
if (idx <= pfp->ctf_typemax)
{
if (idx >= fp->ctf_pptrtab_len
&& grow_pptrtab (fp, pfp->ctf_ptrtab_len) < 0)
return -1; /* errno is set for us. */
fp->ctf_pptrtab[idx] = i;
}
}
}
fp->ctf_pptrtab_typemax = fp->ctf_typemax;
return 0;
}
/* Compare the given input string and length against a table of known C storage
qualifier keywords. We just ignore these in ctf_lookup_by_name, below. To
do this quickly, we use a pre-computed Perfect Hash Function similar to the
technique originally described in the classic paper:
R.J. Cichelli, "Minimal Perfect Hash Functions Made Simple",
Communications of the ACM, Volume 23, Issue 1, January 1980, pp. 17-19.
For an input string S of length N, we use hash H = S[N - 1] + N - 105, which
for the current set of qualifiers yields a unique H in the range [0 .. 20].
The hash can be modified when the keyword set changes as necessary. We also
store the length of each keyword and check it prior to the final strcmp().
TODO: just use gperf. */
static int
isqualifier (const char *s, size_t len)
{
static const struct qual
{
const char *q_name;
size_t q_len;
} qhash[] = {
{"static", 6}, {"", 0}, {"", 0}, {"", 0},
{"volatile", 8}, {"", 0}, {"", 0}, {"", 0}, {"", 0},
{"", 0}, {"auto", 4}, {"extern", 6}, {"", 0}, {"", 0},
{"", 0}, {"", 0}, {"const", 5}, {"register", 8},
{"", 0}, {"restrict", 8}, {"_Restrict", 9}
};
int h = s[len - 1] + (int) len - 105;
const struct qual *qp;
if (h < 0 || (size_t) h >= sizeof (qhash) / sizeof (qhash[0]))
return 0;
qp = &qhash[h];
return ((size_t) len == qp->q_len &&
strncmp (qp->q_name, s, qp->q_len) == 0);
}
/* Find a pointer to type by looking in the's ctf_pptrtab (if child is set) and
fp->ctf_ptrtab. Return -1 / ECTF_NOTYPE if no type exists.
Skip lookups if this is a child type and we are looking in the parent (with
child set), because you cannot have a pointer in the parent to a type in the
child (an earlier loop checks for pointers to child types).
There is extra complexity here because uninitialized elements in the pptrtab
and ptrtab are set to zero, but zero (as the type ID meaning the
unimplemented type) is a valid return type from ctf_lookup_by_name.
(Pointers to types are never of type 0, so this is unambiguous, just fiddly
to deal with.) */
static ctf_id_t
lookup_ptrtab (ctf_dict_t *fp, ctf_dict_t *child, ctf_id_t type, int *in_child)
{
ctf_id_t ntype = 0;
uint32_t idx;
*in_child = 0;
/* If we're looking up types in the parent from the perspective of a child,
don't even try looking if this is a child type: this is done earlier. */
if (child && ctf_type_ischild (fp, type))
return ctf_set_typed_errno (fp, ECTF_NOTYPE);
idx = ctf_type_to_index (fp, type);
ntype = CTF_ERR;
/* Lookup of parent type in child: check pptrtab. */
if (child)
{
if (idx < child->ctf_pptrtab_len)
{
ntype = child->ctf_pptrtab[idx];
if (ntype)
*in_child = 1;
else
ntype = CTF_ERR;
}
}
/* Type, and pointer to it, might still be in the parent: check its ptrtab. */
if (ntype == CTF_ERR)
{
idx = ctf_type_to_index (fp, type);
ntype = fp->ctf_ptrtab[idx];
if (ntype == 0)
ntype = CTF_ERR;
}
if (ntype == CTF_ERR)
return ctf_set_typed_errno (fp, ECTF_NOTYPE);
return ntype;
}
/* Attempt to convert the given C type name into the corresponding CTF type ID.
It is not possible to do complete and proper conversion of type names
without implementing a more full-fledged parser, which is necessary to
handle things like types that are function pointers to functions that
have arguments that are function pointers, and fun stuff like that.
Instead, this function implements a very simple conversion algorithm that
finds the things that we actually care about: structs, unions, enums,
integers, floats, typedefs, and pointers to any of these named types. */
static ctf_id_t
ctf_lookup_by_name_internal (ctf_dict_t *fp, ctf_dict_t *child,
const char *name)
{
static const char delimiters[] = " \t\n\r\v\f*";
const ctf_lookup_t *lp;
const char *p, *q, *end;
ctf_id_t type = 0;
ctf_id_t ntype, ptype;
if (name == NULL)
return (ctf_set_typed_errno (fp, EINVAL));
for (p = name, end = name + strlen (name); *p != '\0'; p = q)
{
while (isspace ((int) *p))
p++; /* Skip leading whitespace. */
if (p == end)
break;
if ((q = strpbrk (p + 1, delimiters)) == NULL)
q = end; /* Compare until end. */
if (*p == '*')
{
/* Find a pointer to type by looking in child->ctf_pptrtab (if child
is set) and fp->ctf_ptrtab. If we can't find a pointer to the
given type, see if we can compute a pointer to the type resulting
from resolving the type down to its base type and use that instead.
This helps with cases where the CTF data includes "struct foo *"
but not "foo_t *" and the user tries to access "foo_t *" in the
debugger. */
int in_child = 0;
/* Parent type, not looking in the parent yet? Do so. */
if (!child && fp->ctf_flags & LCTF_CHILD
&& ctf_type_isparent (fp, type))
goto notype;
ntype = lookup_ptrtab (fp, child, type, &in_child);
/* Try resolving to its base type and check again. */
if (ntype == CTF_ERR && ctf_errno (fp) == ECTF_NOTYPE)
{
int err;
if (child)
{
ntype = ctf_type_resolve_unsliced (child, type);
err = ctf_errno (child);
}
else
{
ntype = ctf_type_resolve_unsliced (fp, type);
err = ctf_errno (fp);
}
if (ntype == CTF_ERR)
{
if (err == ECTF_BADID)
goto notype;
else
return ctf_set_typed_errno (fp, err);
}
ntype = lookup_ptrtab (fp, child, type, &in_child);
}
if (ntype == CTF_ERR)
{
if (ctf_errno (fp) == ECTF_BADID
|| ctf_errno (fp) == ECTF_NOTYPE)
goto notype;
else
return -1; /* errno is set for us. */
}
if (in_child)
type = ctf_index_to_type (child, ntype);
else
type = ctf_index_to_type (fp, ntype);
/* We are looking up a type in the parent, but the pointed-to type is
in the child. Switch to looking in the child: if we need to go
back into the parent, we can recurse again. */
if (in_child)
{
fp = child;
child = NULL;
}
q = p + 1;
continue;
}
if (isqualifier (p, (size_t) (q - p)))
continue; /* Skip qualifier keyword. */
for (lp = fp->ctf_lookups; lp->ctl_prefix != NULL; lp++)
{
/* TODO: This is not MT-safe. */
if ((lp->ctl_prefix[0] == '\0' ||
strncmp (p, lp->ctl_prefix, (size_t) (q - p)) == 0) &&
(size_t) (q - p) >= lp->ctl_len)
{
for (p += lp->ctl_len; isspace ((int) *p); p++)
continue; /* Skip prefix and next whitespace. */
if ((q = strchr (p, '*')) == NULL)
q = end; /* Compare until end. */
while (isspace ((int) q[-1]))
q--; /* Exclude trailing whitespace. */
/* Expand and/or allocate storage for a slice of the name, then
copy it in. */
if (fp->ctf_tmp_typeslicelen >= (size_t) (q - p) + 1)
{
memcpy (fp->ctf_tmp_typeslice, p, (size_t) (q - p));
fp->ctf_tmp_typeslice[(size_t) (q - p)] = '\0';
}
else
{
free (fp->ctf_tmp_typeslice);
fp->ctf_tmp_typeslice = xstrndup (p, (size_t) (q - p));
if (fp->ctf_tmp_typeslice == NULL)
return ctf_set_typed_errno (fp, ENOMEM);
}
if ((type = (ctf_id_t) (uintptr_t)
ctf_dynhash_lookup (lp->ctl_hash,
fp->ctf_tmp_typeslice)) == 0)
goto notype;
break;
}
}
if (lp->ctl_prefix == NULL)
goto notype;
}
if (*p != '\0' || type == 0)
return (ctf_set_typed_errno (fp, ECTF_SYNTAX));
return type;
notype:
ctf_set_errno (fp, ECTF_NOTYPE);
if (fp->ctf_parent != NULL)
{
/* Need to look up in the parent, from the child's perspective.
Make sure the pptrtab is up to date. */
if (fp->ctf_pptrtab_typemax < fp->ctf_typemax)
{
if (refresh_pptrtab (fp, fp->ctf_parent) < 0)
return CTF_ERR; /* errno is set for us. */
}
if ((ptype = ctf_lookup_by_name_internal (fp->ctf_parent, fp,
name)) != CTF_ERR)
return ptype;
return (ctf_set_typed_errno (fp, ctf_errno (fp->ctf_parent)));
}
return CTF_ERR;
}
ctf_id_t
ctf_lookup_by_name (ctf_dict_t *fp, const char *name)
{
if (fp->ctf_flags & LCTF_NO_STR)
return (ctf_set_typed_errno (fp, ECTF_NOPARENT));
return ctf_lookup_by_name_internal (fp, NULL, name);
}
/* Return the pointer to the internal CTF type data corresponding to the given
type ID. If the ID is invalid, the function returns NULL. The type data
returned is the prefix, if this is a a prefixed kind: if SUFFIX is set, also
provide the suffix. If there is no prefix, the SUFFIX is the same as the
return value. (See ctf-open.c's dictops for why.)
This function is not exported outside of the library. */
const ctf_type_t *
ctf_lookup_by_id (ctf_dict_t **fpp, ctf_id_t type, const ctf_type_t **suffix)
{
ctf_dict_t *fp = *fpp;
ctf_id_t idx;
if ((fp = ctf_get_dict (fp, type)) == NULL)
{
(void) ctf_set_errno (*fpp, ECTF_NOPARENT);
return NULL;
}
idx = ctf_type_to_index (fp, type);
if ((unsigned long) idx > fp->ctf_typemax)
{
ctf_set_errno (*fpp, ECTF_BADID);
return NULL;
}
*fpp = fp; /* Possibly the parent CTF dict. */
if (idx > fp->ctf_stypes)
{
ctf_dtdef_t *dtd;
dtd = ctf_dtd_lookup (fp, ctf_index_to_type (fp, idx));
if (suffix)
*suffix = dtd->dtd_data;
return dtd->dtd_buf;
}
else
{
ctf_type_t *tp = fp->ctf_txlate[idx];
if (suffix)
{
ctf_type_t *suff;
suff = tp;
while (LCTF_IS_PREFIXED_INFO (suff->ctt_info))
suff++;
*suffix = suff;
}
return tp;
}
}
/* Find a given prefix in some type, if any. */
const ctf_type_t *
ctf_find_prefix (ctf_dict_t *fp, const ctf_type_t *tp, int kind)
{
uint32_t kind_ = kind;
while (LCTF_IS_PREFIXED_INFO (tp->ctt_info)
&& CTF_INFO_KIND (tp->ctt_info) != kind_)
tp++;
if (LCTF_INFO_UNPREFIXED_KIND (fp, tp->ctt_info) != kind_)
return NULL;
return tp;
}
typedef struct ctf_lookup_idx_key
{
ctf_dict_t *clik_fp;
const char *clik_name;
uint32_t *clik_names;
} ctf_lookup_idx_key_t;
/* A bsearch function for variable names. */
static int
ctf_lookup_var (const void *key_, const void *lookup_)
{
const ctf_lookup_idx_key_t *key = key_;
const ctf_varent_t *lookup = lookup_;
return (strcmp (key->clik_name, ctf_strptr (key->clik_fp, lookup->ctv_name)));
}
/* Given a variable name, return the type of the variable with that name.
Look only in this dict, not in the parent. */
ctf_id_t
ctf_lookup_variable_here (ctf_dict_t *fp, const char *name)
{
ctf_dvdef_t *dvd = ctf_dvd_lookup (fp, name);
ctf_varent_t *ent;
ctf_lookup_idx_key_t key = { fp, name, NULL };
if (dvd != NULL)
return dvd->dvd_type;
/* This array is sorted, so we can bsearch for it. */
ent = bsearch (&key, fp->ctf_vars, fp->ctf_nvars, sizeof (ctf_varent_t),
ctf_lookup_var);
if (ent == NULL)
return (ctf_set_typed_errno (fp, ECTF_NOTYPEDAT));
return ent->ctv_type;
}
/* As above, but look in the parent too. */
ctf_id_t
ctf_lookup_variable (ctf_dict_t *fp, const char *name)
{
ctf_id_t type;
if (fp->ctf_flags & LCTF_NO_STR)
return (ctf_set_typed_errno (fp, ECTF_NOPARENT));
if ((type = ctf_lookup_variable_here (fp, name)) == CTF_ERR)
{
if (ctf_errno (fp) == ECTF_NOTYPEDAT && fp->ctf_parent != NULL)
{
if ((type = ctf_lookup_variable_here (fp->ctf_parent, name)) != CTF_ERR)
return type;
return (ctf_set_typed_errno (fp, ctf_errno (fp->ctf_parent)));
}
return -1; /* errno is set for us. */
}
return type;
}
/* Look up a single enumerator by enumeration constant name. Returns the ID of
the enum it is contained within and optionally its value. Error out with
ECTF_DUPLICATE if multiple exist (which can happen in some older dicts). See
ctf_lookup_enumerator_next in that case. Enumeration constants in non-root
types are not returned, but constants in parents are, if not overridden by
an enum in the child.. */
ctf_id_t
ctf_lookup_enumerator (ctf_dict_t *fp, const char *name, int64_t *enum_value)
{
ctf_id_t type;
int enum_int_value;
if (fp->ctf_flags & LCTF_NO_STR)
return (ctf_set_typed_errno (fp, ECTF_NOPARENT));
if (ctf_dynset_lookup (fp->ctf_conflicting_enums, name))
return (ctf_set_typed_errno (fp, ECTF_DUPLICATE));
/* CTF_K_UNKNOWN suffices for things like enumeration constants that aren't
actually types at all (ending up in the global name table). */
type = ctf_lookup_by_rawname (fp, CTF_K_UNKNOWN, name);
/* Nonexistent type? It may be in the parent. */
if (type == 0 && fp->ctf_parent)
{
if ((type = ctf_lookup_enumerator (fp->ctf_parent, name, enum_value)) == 0)
return ctf_set_typed_errno (fp, ECTF_NOENUMNAM);
return type;
}
/* Nothing more to do if this type didn't exist or we don't have to look up
the enum value. */
if (type == 0)
return ctf_set_typed_errno (fp, ECTF_NOENUMNAM);
if (enum_value == NULL)
return type;
if (ctf_enum_value (fp, type, name, &enum_int_value) < 0)
return CTF_ERR;
*enum_value = enum_int_value;
return type;
}
/* Return all enumeration constants with a given name in a given dict, similar
to ctf_lookup_enumerator above but capable of returning multiple values.
Enumerators in parent dictionaries are not returned: enumerators in
hidden types *are* returned. */
ctf_id_t
ctf_lookup_enumerator_next (ctf_dict_t *fp, const char *name,
ctf_next_t **it, int64_t *val)
{
ctf_next_t *i = *it;
int found = 0;
if (fp->ctf_flags & LCTF_NO_STR)
return (ctf_set_typed_errno (fp, ECTF_NOPARENT));
/* We use ctf_type_next() to iterate across all types, but then traverse each
enumerator found by hand: traversing enumerators is very easy, and it would
probably be more confusing to use two nested iterators than to do it this
way. We use ctn_next to work over enums, then ctn_en and ctn_n to work
over enumerators within each enum. */
if (!i)
{
if ((i = ctf_next_create ()) == NULL)
return ctf_set_typed_errno (fp, ENOMEM);
i->cu.ctn_fp = fp;
i->ctn_iter_fun = (void (*) (void)) ctf_lookup_enumerator_next;
i->ctn_increment = 0;
i->ctn_tp = NULL;
i->u.ctn_en = NULL;
i->ctn_n = 0;
*it = i;
}
if ((void (*) (void)) ctf_lookup_enumerator_next != i->ctn_iter_fun)
return (ctf_set_typed_errno (fp, ECTF_NEXT_WRONGFUN));
if (fp != i->cu.ctn_fp)
return (ctf_set_typed_errno (fp, ECTF_NEXT_WRONGFP));
do
{
const char *this_name;
/* At end of enum? Traverse to next one, if any are left. */
if (i->u.ctn_en == NULL || i->ctn_n == 0)
{
const ctf_type_t *tp;
ctf_dtdef_t *dtd;
do
i->ctn_type = ctf_type_next (i->cu.ctn_fp, &i->ctn_next, NULL, 1);
while (i->ctn_type != CTF_ERR
&& ctf_type_kind_unsliced (i->cu.ctn_fp, i->ctn_type)
!= CTF_K_ENUM);
if (i->ctn_type == CTF_ERR)
{
/* Conveniently, when the iterator over all types is done, so is the
iteration as a whole: so we can just pass all errors from the
internal iterator straight back out.. */
ctf_next_destroy (i);
*it = NULL;
return CTF_ERR; /* errno is set for us. */
}
if ((tp = ctf_lookup_by_id (&fp, i->ctn_type)) == NULL)
return CTF_ERR; /* errno is set for us. */
i->ctn_n = LCTF_INFO_VLEN (fp, tp->ctt_info);
dtd = ctf_dynamic_type (fp, i->ctn_type);
if (dtd == NULL)
{
(void) ctf_get_ctt_size (fp, tp, NULL, &i->ctn_increment);
i->u.ctn_en = (const ctf_enum_t *) ((uintptr_t) tp +
i->ctn_increment);
}
else
i->u.ctn_en = (const ctf_enum_t *) dtd->dtd_vlen;
}
this_name = ctf_strptr (fp, i->u.ctn_en->cte_name);
i->ctn_n--;
if (strcmp (name, this_name) == 0)
{
if (val)
*val = i->u.ctn_en->cte_value;
found = 1;
/* Constant found in this enum: try the next one. (Constant names
cannot be duplicated within a given enum.) */
i->ctn_n = 0;
}
i->u.ctn_en++;
}
while (!found);
return i->ctn_type;
}
typedef struct ctf_symidx_sort_arg_cb
{
ctf_dict_t *fp;
uint32_t *names;
} ctf_symidx_sort_arg_cb_t;
static int
sort_symidx_by_name (const void *one_, const void *two_, void *arg_)
{
const uint32_t *one = one_;
const uint32_t *two = two_;
ctf_symidx_sort_arg_cb_t *arg = arg_;
return (strcmp (ctf_strptr (arg->fp, arg->names[*one]),
ctf_strptr (arg->fp, arg->names[*two])));
}
/* Sort a symbol index section by name. Takes a 1:1 mapping of names to the
corresponding symbol table. Returns a lexicographically sorted array of idx
indexes (and thus, of indexes into the corresponding func info / data object
section). */
static uint32_t *
ctf_symidx_sort (ctf_dict_t *fp, uint32_t *idx, size_t *nidx,
size_t len)
{
uint32_t *sorted;
size_t i;
if ((sorted = malloc (len)) == NULL)
{
ctf_set_errno (fp, ENOMEM);
return NULL;
}
*nidx = len / sizeof (uint32_t);
for (i = 0; i < *nidx; i++)
sorted[i] = i;
if (!(fp->ctf_header->cth_flags & CTF_F_IDXSORTED))
{
ctf_symidx_sort_arg_cb_t arg = { fp, idx };
ctf_dprintf ("Index section unsorted: sorting.\n");
ctf_qsort_r (sorted, *nidx, sizeof (uint32_t), sort_symidx_by_name, &arg);
fp->ctf_header->cth_flags |= CTF_F_IDXSORTED;
}
return sorted;
}
/* Given a symbol index, return the name of that symbol from the table provided
by ctf_link_shuffle_syms, or failing that from the secondary string table, or
the null string. */
static const char *
ctf_lookup_symbol_name (ctf_dict_t *fp, unsigned long symidx)
{
const ctf_sect_t *sp = &fp->ctf_ext_symtab;
ctf_link_sym_t sym;
int err;
if (fp->ctf_dynsymidx)
{
err = EINVAL;
if (symidx > fp->ctf_dynsymmax)
goto try_parent;
ctf_link_sym_t *symp = fp->ctf_dynsymidx[symidx];
if (!symp)
goto try_parent;
return symp->st_name;
}
err = ECTF_NOSYMTAB;
if (sp->cts_data == NULL)
goto try_parent;
if (symidx >= fp->ctf_nsyms)
goto try_parent;
switch (sp->cts_entsize)
{
case sizeof (Elf64_Sym):
{
const Elf64_Sym *symp = (Elf64_Sym *) sp->cts_data + symidx;
ctf_elf64_to_link_sym (fp, &sym, symp, symidx);
}
break;
case sizeof (Elf32_Sym):
{
const Elf32_Sym *symp = (Elf32_Sym *) sp->cts_data + symidx;
ctf_elf32_to_link_sym (fp, &sym, symp, symidx);
}
break;
default:
ctf_set_errno (fp, ECTF_SYMTAB);
return _CTF_NULLSTR;
}
assert (!sym.st_nameidx_set);
return sym.st_name;
try_parent:
if (fp->ctf_parent)
{
const char *ret;
ret = ctf_lookup_symbol_name (fp->ctf_parent, symidx);
if (ret == NULL)
ctf_set_errno (fp, ctf_errno (fp->ctf_parent));
return ret;
}
else
{
ctf_set_errno (fp, err);
return _CTF_NULLSTR;
}
}
/* Given a symbol name, return the index of that symbol, or -1 on error or if
not found. If is_function is >= 0, return only function or data object
symbols, respectively. */
static unsigned long
ctf_lookup_symbol_idx (ctf_dict_t *fp, const char *symname, int try_parent,
int is_function)
{
const ctf_sect_t *sp = &fp->ctf_ext_symtab;
ctf_link_sym_t sym;
void *known_idx;
int err;
ctf_dict_t *cache = fp;
if (fp->ctf_dynsyms)
{
err = EINVAL;
ctf_link_sym_t *symp;
if (((symp = ctf_dynhash_lookup (fp->ctf_dynsyms, symname)) == NULL)
|| (symp->st_type != STT_OBJECT && is_function == 0)
|| (symp->st_type != STT_FUNC && is_function == 1))
goto try_parent;
return symp->st_symidx;
}
err = ECTF_NOSYMTAB;
if (sp->cts_data == NULL)
goto try_parent;
/* First, try a hash lookup to see if we have already spotted this symbol
during a past iteration: create the hash first if need be. The
lifespan of the strings is equal to the lifespan of the cts_data, so we
don't need to strdup them. If this dict was opened as part of an
archive, and this archive has a crossdict_cache to cache results that
are the same across all dicts in an archive, use it. */
if (fp->ctf_archive && fp->ctf_archive->ctfi_crossdict_cache)
cache = fp->ctf_archive->ctfi_crossdict_cache;
if (!cache->ctf_symhash_func)
if ((cache->ctf_symhash_func = ctf_dynhash_create (ctf_hash_string,
ctf_hash_eq_string,
NULL, NULL)) == NULL)
goto oom;
if (!cache->ctf_symhash_objt)
if ((cache->ctf_symhash_objt = ctf_dynhash_create (ctf_hash_string,
ctf_hash_eq_string,
NULL, NULL)) == NULL)
goto oom;
if (is_function != 0 &&
ctf_dynhash_lookup_kv (cache->ctf_symhash_func, symname, NULL, &known_idx))
return (unsigned long) (uintptr_t) known_idx;
if (is_function != 1 &&
ctf_dynhash_lookup_kv (cache->ctf_symhash_objt, symname, NULL, &known_idx))
return (unsigned long) (uintptr_t) known_idx;
/* Hash lookup unsuccessful: linear search, populating the hashtab for later
lookups as we go. */
for (; cache->ctf_symhash_latest < sp->cts_size / sp->cts_entsize;
cache->ctf_symhash_latest++)
{
ctf_dynhash_t *h;
switch (sp->cts_entsize)
{
case sizeof (Elf64_Sym):
{
Elf64_Sym *symp = (Elf64_Sym *) sp->cts_data;
ctf_elf64_to_link_sym (fp, &sym, &symp[cache->ctf_symhash_latest],
cache->ctf_symhash_latest);
}
break;
case sizeof (Elf32_Sym):
{
Elf32_Sym *symp = (Elf32_Sym *) sp->cts_data;
ctf_elf32_to_link_sym (fp, &sym, &symp[cache->ctf_symhash_latest],
cache->ctf_symhash_latest);
break;
}
default:
ctf_set_errno (fp, ECTF_SYMTAB);
return (unsigned long) -1;
}
if (sym.st_type == STT_FUNC)
h = cache->ctf_symhash_func;
else if (sym.st_type == STT_OBJECT)
h = cache->ctf_symhash_objt;
else
continue; /* Not of interest. */
if (!ctf_dynhash_lookup_kv (h, sym.st_name,
NULL, NULL))
if (ctf_dynhash_cinsert (h, sym.st_name,
(const void *) (uintptr_t)
cache->ctf_symhash_latest) < 0)
goto oom;
if (strcmp (sym.st_name, symname) == 0)
return cache->ctf_symhash_latest++;
}
/* Searched everything, still not found. */
return (unsigned long) -1;
try_parent:
if (fp->ctf_parent && try_parent)
{
unsigned long psym;
if ((psym = ctf_lookup_symbol_idx (fp->ctf_parent, symname, try_parent,
is_function))
!= (unsigned long) -1)
return psym;
ctf_set_errno (fp, ctf_errno (fp->ctf_parent));
return (unsigned long) -1;
}
else
{
ctf_set_errno (fp, err);
return (unsigned long) -1;
}
oom:
ctf_set_errno (fp, ENOMEM);
ctf_err_warn (fp, 0, 0, _("cannot allocate memory for symbol "
"lookup hashtab"));
return (unsigned long) -1;
}
ctf_id_t
ctf_symbol_next_static (ctf_dict_t *fp, ctf_next_t **it, const char **name,
int functions);
/* Iterate over all symbols with types: if FUNC, function symbols,
otherwise, data symbols. The name argument is not optional. The return
order is arbitrary, though is likely to be in symbol index or name order.
Changing the value of 'functions' in the middle of iteration has
unpredictable effects (probably skipping symbols, etc) and is not
recommended. Adding symbols while iteration is underway may also lead
to other symbols being skipped. */
ctf_id_t
ctf_symbol_next (ctf_dict_t *fp, ctf_next_t **it, const char **name,
int functions)
{
ctf_id_t sym = CTF_ERR;
ctf_next_t *i = *it;
int err;
if (fp->ctf_flags & LCTF_NO_STR)
return (ctf_set_typed_errno (fp, ECTF_NOPARENT));
if (!i)
{
if ((i = ctf_next_create ()) == NULL)
return ctf_set_typed_errno (fp, ENOMEM);
i->cu.ctn_fp = fp;
i->ctn_iter_fun = (void (*) (void)) ctf_symbol_next;
i->ctn_n = 0;
*it = i;
}
if ((void (*) (void)) ctf_symbol_next != i->ctn_iter_fun)
return (ctf_set_typed_errno (fp, ECTF_NEXT_WRONGFUN));
if (fp != i->cu.ctn_fp)
return (ctf_set_typed_errno (fp, ECTF_NEXT_WRONGFP));
/* Check the dynamic set of names first, to allow previously-written names
to be replaced with dynamic ones (there is still no way to remove them,
though).
We intentionally use raw access, not ctf_lookup_by_symbol, to avoid
incurring additional sorting cost for unsorted symtypetabs coming from the
compiler, to allow ctf_symbol_next to work in the absence of a symtab, and
finally because it's easier to work out what the name of each symbol is if
we do that. */
ctf_dynhash_t *dynh = functions ? fp->ctf_funchash : fp->ctf_objthash;
void *dyn_name = NULL, *dyn_value = NULL;
size_t dyn_els = dynh ? ctf_dynhash_elements (dynh) : 0;
if (i->ctn_n < dyn_els)
{
err = ctf_dynhash_next (dynh, &i->ctn_next, &dyn_name, &dyn_value);
/* This covers errors and also end-of-iteration. */
if (err != 0)
{
ctf_next_destroy (i);
*it = NULL;
return ctf_set_typed_errno (fp, err);
}
*name = dyn_name;
sym = (ctf_id_t) (uintptr_t) dyn_value;
i->ctn_n++;
return sym;
}
return ctf_symbol_next_static (fp, it, name, functions);
}
/* ctf_symbol_next, but only for static symbols. Mostly an internal
implementation detail of ctf_symbol_next, but also used to simplify
serialization. */
ctf_id_t
ctf_symbol_next_static (ctf_dict_t *fp, ctf_next_t **it, const char **name,
int functions)
{
ctf_id_t sym = CTF_ERR;
ctf_next_t *i = *it;
ctf_dynhash_t *dynh = functions ? fp->ctf_funchash : fp->ctf_objthash;
size_t dyn_els = dynh ? ctf_dynhash_elements (dynh) : 0;
/* Only relevant for direct internal-to-library calls, not via
ctf_symbol_next (but important then). */
if (!i)
{
if ((i = ctf_next_create ()) == NULL)
return ctf_set_typed_errno (fp, ENOMEM);
i->cu.ctn_fp = fp;
i->ctn_iter_fun = (void (*) (void)) ctf_symbol_next;
i->ctn_n = dyn_els;
*it = i;
}
if ((void (*) (void)) ctf_symbol_next != i->ctn_iter_fun)
return (ctf_set_typed_errno (fp, ECTF_NEXT_WRONGFUN));
if (fp != i->cu.ctn_fp)
return (ctf_set_typed_errno (fp, ECTF_NEXT_WRONGFP));
/* TODO-v4: Indexed after non-indexed portions? */
if ((!functions && fp->ctf_objtidx_names) ||
(functions && fp->ctf_funcidx_names))
{
ctf_header_t *hp = fp->ctf_header;
uint32_t *idx = functions ? fp->ctf_funcidx_names : fp->ctf_objtidx_names;
uint32_t *tab;
size_t len;
if (functions)
{
len = (hp->cth_varoff - hp->cth_funcidxoff) / sizeof (uint32_t);
tab = (uint32_t *) (fp->ctf_buf + hp->cth_funcoff);
}
else
{
len = (hp->cth_funcidxoff - hp->cth_objtidxoff) / sizeof (uint32_t);
tab = (uint32_t *) (fp->ctf_buf + hp->cth_objtoff);
}
do
{
if (i->ctn_n - dyn_els >= len)
goto end;
*name = ctf_strptr (fp, idx[i->ctn_n - dyn_els]);
sym = tab[i->ctn_n - dyn_els];
i->ctn_n++;
}
while (sym == -1u || sym == 0);
}
else
{
/* Skip over pads in ctf_sxlate, padding for typeless symbols in the
symtypetab itself, and symbols in the wrong table. */
for (; i->ctn_n - dyn_els < fp->ctf_nsyms; i->ctn_n++)
{
ctf_header_t *hp = fp->ctf_header;
size_t n = i->ctn_n - dyn_els;
if (fp->ctf_sxlate[n] == -1u)
continue;
sym = *(uint32_t *) ((uintptr_t) fp->ctf_buf + fp->ctf_sxlate[n]);
if (sym == 0)
continue;
if (functions)
{
if (fp->ctf_sxlate[n] >= hp->cth_funcoff
&& fp->ctf_sxlate[n] < hp->cth_objtidxoff)
break;
}
else
{
if (fp->ctf_sxlate[n] >= hp->cth_objtoff
&& fp->ctf_sxlate[n] < hp->cth_funcoff)
break;
}
}
if (i->ctn_n - dyn_els >= fp->ctf_nsyms)
goto end;
*name = ctf_lookup_symbol_name (fp, i->ctn_n - dyn_els);
i->ctn_n++;
}
return sym;
end:
ctf_next_destroy (i);
*it = NULL;
return (ctf_set_typed_errno (fp, ECTF_NEXT_END));
}
/* A bsearch function for function and object index names. */
static int
ctf_lookup_idx_name (const void *key_, const void *idx_)
{
const ctf_lookup_idx_key_t *key = key_;
const uint32_t *idx = idx_;
return (strcmp (key->clik_name, ctf_strptr (key->clik_fp, key->clik_names[*idx])));
}
/* Given a symbol name or (failing that) number, look up that symbol in the
function or object index table (which must exist). Return 0 if not found
there (or pad). */
static ctf_id_t
ctf_try_lookup_indexed (ctf_dict_t *fp, unsigned long symidx,
const char *symname, int is_function)
{
struct ctf_header *hp = fp->ctf_header;
uint32_t *symtypetab;
uint32_t *names;
uint32_t *sxlate;
size_t nidx;
if (symname == NULL)
symname = ctf_lookup_symbol_name (fp, symidx);
/* Dynamic dict with no static portion: just return. */
if (!hp)
{
ctf_dprintf ("%s not found in idx: dict is dynamic\n", symname);
return 0;
}
ctf_dprintf ("Looking up type of object with symtab idx %lx or name %s in "
"indexed symtypetab\n", symidx, symname);
if (symname[0] == '\0')
return CTF_ERR; /* errno is set for us. */
if (is_function)
{
if (!fp->ctf_funcidx_sxlate)
{
if ((fp->ctf_funcidx_sxlate
= ctf_symidx_sort (fp, (uint32_t *)
(fp->ctf_buf + hp->cth_funcidxoff),
&fp->ctf_nfuncidx,
hp->cth_varoff - hp->cth_funcidxoff))
== NULL)
{
ctf_err_warn (fp, 0, 0, _("cannot sort function symidx"));
return CTF_ERR; /* errno is set for us. */
}
}
symtypetab = (uint32_t *) (fp->ctf_buf + hp->cth_funcoff);
sxlate = fp->ctf_funcidx_sxlate;
names = fp->ctf_funcidx_names;
nidx = fp->ctf_nfuncidx;
}
else
{
if (!fp->ctf_objtidx_sxlate)
{
if ((fp->ctf_objtidx_sxlate
= ctf_symidx_sort (fp, (uint32_t *)
(fp->ctf_buf + hp->cth_objtidxoff),
&fp->ctf_nobjtidx,
hp->cth_funcidxoff - hp->cth_objtidxoff))
== NULL)
{
ctf_err_warn (fp, 0, 0, _("cannot sort object symidx"));
return CTF_ERR; /* errno is set for us. */
}
}
symtypetab = (uint32_t *) (fp->ctf_buf + hp->cth_objtoff);
sxlate = fp->ctf_objtidx_sxlate;
names = fp->ctf_objtidx_names;
nidx = fp->ctf_nobjtidx;
}
ctf_lookup_idx_key_t key = { fp, symname, names };
uint32_t *idx;
idx = bsearch (&key, sxlate, nidx, sizeof (uint32_t), ctf_lookup_idx_name);
if (!idx)
{
ctf_dprintf ("%s not found in idx\n", symname);
return 0;
}
/* Should be impossible, but be paranoid. */
if ((idx - sxlate) > (ptrdiff_t) nidx)
return (ctf_set_typed_errno (fp, ECTF_CORRUPT));
ctf_dprintf ("Symbol %lx (%s) is of type %x\n", symidx, symname,
symtypetab[*idx]);
return symtypetab[*idx];
}
/* Given a symbol name or (if NULL) symbol index, return the type of the
function or data object described by the corresponding entry in the symbol
table. We can only return symbols in read-only dicts and in dicts for which
ctf_link_shuffle_syms has been called to assign symbol indexes to symbol
names.
If try_parent is false, do not check the parent dict too.
If is_function is > -1, only look for data objects or functions in
particular. */
ctf_id_t
ctf_lookup_by_sym_or_name (ctf_dict_t *fp, unsigned long symidx,
const char *symname, int try_parent,
int is_function)
{
const ctf_sect_t *sp = &fp->ctf_ext_symtab;
ctf_id_t type = 0;
int err = 0;
/* Shuffled dynsymidx present? Use that. For now, the dynsymidx and
shuffled-symbol lookup only support dynamically-added symbols, because
this interface is meant for use by linkers, and linkers are only going
to report symbols against newly-created, freshly-ctf_link'ed dicts: so
there will be no static component in any case. */
if (fp->ctf_dynsymidx)
{
const ctf_link_sym_t *sym;
if (symname)
ctf_dprintf ("Looking up type of object with symname %s in "
"writable dict symtypetab\n", symname);
else
ctf_dprintf ("Looking up type of object with symtab idx %lx in "
"writable dict symtypetab\n", symidx);
/* No name? Need to look it up. */
if (!symname)
{
err = EINVAL;
if (symidx > fp->ctf_dynsymmax)
goto try_parent;
sym = fp->ctf_dynsymidx[symidx];
err = ECTF_NOTYPEDAT;
if (!sym || (sym->st_type != STT_OBJECT && sym->st_type != STT_FUNC)
|| (sym->st_type != STT_OBJECT && is_function == 0)
|| (sym->st_type != STT_FUNC && is_function == 1))
goto try_parent;
if (!ctf_assert (fp, !sym->st_nameidx_set))
return CTF_ERR;
symname = sym->st_name;
}
if (fp->ctf_objthash == NULL
|| is_function == 1
|| (type = (ctf_id_t) (uintptr_t)
ctf_dynhash_lookup (fp->ctf_objthash, symname)) == 0)
{
if (fp->ctf_funchash == NULL
|| is_function == 0
|| (type = (ctf_id_t) (uintptr_t)
ctf_dynhash_lookup (fp->ctf_funchash, symname)) == 0)
goto try_parent;
}
return type;
}
/* Dict not shuffled: look for a dynamic sym first, and look it up
directly. */
if (symname)
{
if (fp->ctf_objthash != NULL
&& is_function != 1
&& ((type = (ctf_id_t) (uintptr_t)
ctf_dynhash_lookup (fp->ctf_objthash, symname)) != 0))
return type;
if (fp->ctf_funchash != NULL
&& is_function != 0
&& ((type = (ctf_id_t) (uintptr_t)
ctf_dynhash_lookup (fp->ctf_funchash, symname)) != 0))
return type;
}
err = ECTF_NOSYMTAB;
if (sp->cts_data == NULL && symname == NULL &&
((is_function && !fp->ctf_funcidx_names) ||
(!is_function && !fp->ctf_objtidx_names)))
goto try_parent;
/* This covers both out-of-range lookups by index and a dynamic dict which
hasn't been shuffled yet. */
err = EINVAL;
if (symname == NULL && symidx >= fp->ctf_nsyms)
goto try_parent;
/* Try an indexed lookup. We can only do indexed lookups if we have a string
table. */
if (fp->ctf_objtidx_names && is_function != 1)
{
if (fp->ctf_flags & LCTF_NO_STR)
return (ctf_set_typed_errno (fp, ECTF_NOPARENT));
if ((type = ctf_try_lookup_indexed (fp, symidx, symname, 0)) == CTF_ERR)
return CTF_ERR; /* errno is set for us. */
}
if (type == 0 && fp->ctf_funcidx_names && is_function != 0)
{
if (fp->ctf_flags & LCTF_NO_STR)
return (ctf_set_typed_errno (fp, ECTF_NOPARENT));
if ((type = ctf_try_lookup_indexed (fp, symidx, symname, 1)) == CTF_ERR)
return CTF_ERR; /* errno is set for us. */
}
if (type != 0)
return type;
/* Indexed but no symbol found -> not present, try the parent. */
err = ECTF_NOTYPEDAT;
if (fp->ctf_objtidx_names && fp->ctf_funcidx_names)
goto try_parent;
/* Table must be nonindexed. */
ctf_dprintf ("Looking up object type %lx in 1:1 dict symtypetab\n", symidx);
if (symname != NULL)
if ((symidx = ctf_lookup_symbol_idx (fp, symname, try_parent, is_function))
== (unsigned long) -1)
goto try_parent;
if (fp->ctf_sxlate[symidx] == -1u)
goto try_parent;
type = *(uint32_t *) ((uintptr_t) fp->ctf_buf + fp->ctf_sxlate[symidx]);
if (type == 0)
goto try_parent;
return type;
try_parent:
if (!try_parent)
return ctf_set_errno (fp, err);
if (fp->ctf_parent)
{
ctf_id_t ret = ctf_lookup_by_sym_or_name (fp->ctf_parent, symidx,
symname, try_parent,
is_function);
if (ret == CTF_ERR)
ctf_set_errno (fp, ctf_errno (fp->ctf_parent));
return ret;
}
else
return (ctf_set_typed_errno (fp, err));
}
/* Given a symbol table index, return the type of the function or data object
described by the corresponding entry in the symbol table. */
ctf_id_t
ctf_lookup_by_symbol (ctf_dict_t *fp, unsigned long symidx)
{
return ctf_lookup_by_sym_or_name (fp, symidx, NULL, 1, -1);
}
/* Given a symbol name, return the type of the function or data object described
by the corresponding entry in the symbol table. */
ctf_id_t
ctf_lookup_by_symbol_name (ctf_dict_t *fp, const char *symname)
{
return ctf_lookup_by_sym_or_name (fp, 0, symname, 1, -1);
}
/* Given a symbol table index, return the info for the function described
by the corresponding entry in the symbol table, which may be a function
symbol or may be a data symbol that happens to be a function pointer. */
int
ctf_func_info (ctf_dict_t *fp, unsigned long symidx, ctf_funcinfo_t *fip)
{
ctf_id_t type;
if ((type = ctf_lookup_by_symbol (fp, symidx)) == CTF_ERR)
return -1; /* errno is set for us. */
if (ctf_type_kind (fp, type) != CTF_K_FUNCTION)
return (ctf_set_errno (fp, ECTF_NOTFUNC));
return ctf_func_type_info (fp, type, fip);
}
/* Given a symbol table index, return the arguments for the function described
by the corresponding entry in the symbol table. */
int
ctf_func_args (ctf_dict_t *fp, unsigned long symidx, uint32_t argc,
ctf_id_t *argv)
{
ctf_id_t type;
if ((type = ctf_lookup_by_symbol (fp, symidx)) == CTF_ERR)
return -1; /* errno is set for us. */
if (ctf_type_kind (fp, type) != CTF_K_FUNCTION)
return (ctf_set_errno (fp, ECTF_NOTFUNC));
return ctf_func_type_args (fp, type, argc, argv);
}
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