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binutils-gdb/libctf/ctf-impl.h
Nick Alcock 1136c37971 libctf: symbol type linking support 
This adds facilities to write out the function info and data object
sections, which efficiently map from entries in the symbol table to
types.  The write-side code is entirely new: the read-side code was
merely significantly changed and support for indexed tables added
(pointed to by the no-longer-unused cth_objtidxoff and cth_funcidxoff
header fields).

With this in place, you can use ctf_lookup_by_symbol to look up the
types of symbols of function and object type (and, as before, you can
use ctf_lookup_variable to look up types of file-scope variables not
present in the symbol table, as long as you know their name: but
variables that are also data objects are now found in the data object
section instead.)

(Compatible) file format change:

The CTF spec has always said that the function info section looks much
like the CTF_K_FUNCTIONs in the type section: an info word (including an
argument count) followed by a return type and N argument types. This
format is suboptimal: it means function symbols cannot be deduplicated
and it causes a lot of ugly code duplication in libctf.  But
conveniently the compiler has never emitted this!  Because it has always
emitted a rather different format that libctf has never accepted, we can
be sure that there are no instances of this function info section in the
wild, and can freely change its format without compatibility concerns or
a file format version bump.  (And since it has never been emitted in any
code that generated any older file format version, either, we need keep
no code to read the format as specified at all!)

So the function info section is now specified as an array of uint32_t,
exactly like the object data section: each entry is a type ID in the
type section which must be of kind CTF_K_FUNCTION, the prototype of
this function.

This allows function types to be deduplicated and also correctly encodes
the fact that all functions declared in C really are types available to
the program: so they should be stored in the type section like all other
types.  (In format v4, we will be able to represent the types of static
functions as well, but that really does require a file format change.)

We introduce a new header flag, CTF_F_NEWFUNCINFO, which is set if the
new function info format is in use.  A sufficiently new compiler will
always set this flag.  New libctf will always set this flag: old libctf
will refuse to open any CTF dicts that have this flag set.  If the flag
is not set on a dict being read in, new libctf will disregard the
function info section.  Format v4 will remove this flag (or, rather, the
flag has no meaning there and the bit position may be recycled for some
other purpose).

New API:

Symbol addition:
  ctf_add_func_sym: Add a symbol with a given name and type.  The
                    type must be of kind CTF_K_FUNCTION (a function
                    pointer).  Internally this adds a name -> type
                    mapping to the ctf_funchash in the ctf_dict.
  ctf_add_objt_sym: Add a symbol with a given name and type.  The type
                    kind can be anything, including function pointers.
		    This adds to ctf_objthash.

These both treat symbols as name -> type mappings: the linker associates
symbol names with symbol indexes via the ctf_link_shuffle_syms callback,
which sets up the ctf_dynsyms/ctf_dynsymidx/ctf_dynsymmax fields in the
ctf_dict.  Repeated relinks can add more symbols.

Variables that are also exposed as symbols are removed from the variable
section at serialization time.

CTF symbol type sections which have enough pads, defined by
CTF_INDEX_PAD_THRESHOLD (whether because they are in dicts with symbols
where most types are unknown, or in archive where most types are defined
in some child or parent dict, not in this specific dict) are sorted by
name rather than symidx and accompanied by an index which associates
each symbol type entry with a name: the existing ctf_lookup_by_symbol
will map symbol indexes to symbol names and look the names up in the
index automatically.  (This is currently ELF-symbol-table-dependent, but
there is almost nothing specific to ELF in here and we can add support
for other symbol table formats easily).

The compiler also uses index sections to communicate the contents of
object file symbol tables without relying on any specific ordering of
symbols: it doesn't need to sort them, and libctf will detect an
unsorted index section via the absence of the new CTF_F_IDXSORTED header
flag, and sort it if needed.

Iteration:
  ctf_symbol_next: Iterator which returns the types and names of symbols
                   one by one, either for function or data symbols.

This does not require any sorting: the ctf_link machinery uses it to
pull in all the compiler-provided symbols cheaply, but it is not
restricted to that use.

(Compatible) changes in API:
  ctf_lookup_by_symbol: can now be called for object and function
                        symbols: never returns ECTF_NOTDATA (which is
			now not thrown by anything, but is kept for
                        compatibility and because it is a plausible
                        error that we might start throwing again at some
                        later date).

Internally we also have changes to the ctf-string functionality so that
"external" strings (those where we track a string -> offset mapping, but
only write out an offset) can be consulted via the usual means
(ctf_strptr) before the strtab is written out.  This is important
because ctf_link_add_linker_symbol can now be handed symbols named via
strtab offsets, and ctf_link_shuffle_syms must figure out their actual
names by looking in the external symtab we have just been fed by the
ctf_link_add_strtab callback, long before that strtab is written out.

include/ChangeLog
2020-11-20  Nick Alcock  <nick.alcock@oracle.com>

	* ctf-api.h (ctf_symbol_next): New.
	(ctf_add_objt_sym): Likewise.
	(ctf_add_func_sym): Likewise.
	* ctf.h: Document new function info section format.
	(CTF_F_NEWFUNCINFO): New.
	(CTF_F_IDXSORTED): New.
	(CTF_F_MAX): Adjust accordingly.

libctf/ChangeLog
2020-11-20  Nick Alcock  <nick.alcock@oracle.com>

	* ctf-impl.h (CTF_INDEX_PAD_THRESHOLD): New.
	(_libctf_nonnull_): Likewise.
	(ctf_in_flight_dynsym_t): New.
	(ctf_dict_t) <ctf_funcidx_names>: Likewise.
	<ctf_objtidx_names>: Likewise.
	<ctf_nfuncidx>: Likewise.
	<ctf_nobjtidx>: Likewise.
	<ctf_funcidx_sxlate>: Likewise.
	<ctf_objtidx_sxlate>: Likewise.
	<ctf_objthash>: Likewise.
	<ctf_funchash>: Likewise.
	<ctf_dynsyms>: Likewise.
	<ctf_dynsymidx>: Likewise.
	<ctf_dynsymmax>: Likewise.
	<ctf_in_flight_dynsym>: Likewise.
	(struct ctf_next) <u.ctn_next>: Likewise.
	(ctf_symtab_skippable): New prototype.
	(ctf_add_funcobjt_sym): Likewise.
	(ctf_dynhash_sort_by_name): Likewise.
	(ctf_sym_to_elf64): Rename to...
	(ctf_elf32_to_link_sym): ... this, and...
	(ctf_elf64_to_link_sym): ... this.
	* ctf-open.c (init_symtab): Check for lack of CTF_F_NEWFUNCINFO
	flag, and presence of index sections.  Refactor out
	ctf_symtab_skippable and ctf_elf*_to_link_sym, and use them.  Use
	ctf_link_sym_t, not Elf64_Sym.  Skip initializing objt or func
	sxlate sections if corresponding index section is present.  Adjust
	for new func info section format.
	(ctf_bufopen_internal): Add ctf_err_warn to corrupt-file error
	handling.  Report incorrect-length index sections.  Always do an
	init_symtab, even if there is no symtab section (there may be index
	sections still).
	(flip_objts): Adjust comment: func and objt sections are actually
	identical in structure now, no need to caveat.
	(ctf_dict_close):  Free newly-added data structures.
	* ctf-create.c (ctf_create): Initialize them.
	(ctf_symtab_skippable): New, refactored out of
	init_symtab, with st_nameidx_set check added.
	(ctf_add_funcobjt_sym): New, add a function or object symbol to the
	ctf_objthash or ctf_funchash, by name.
	(ctf_add_objt_sym): Call it.
	(ctf_add_func_sym): Likewise.
	(symtypetab_delete_nonstatic_vars): New, delete vars also present as
	data objects.
	(CTF_SYMTYPETAB_EMIT_FUNCTION): New flag to symtypetab emitters:
	this is a function emission, not a data object emission.
	(CTF_SYMTYPETAB_EMIT_PAD): New flag to symtypetab emitters: emit
	pads for symbols with no type (only set for unindexed sections).
	(CTF_SYMTYPETAB_FORCE_INDEXED): New flag to symtypetab emitters:
	always emit indexed.
	(symtypetab_density): New, figure out section sizes.
	(emit_symtypetab): New, emit a symtypetab.
	(emit_symtypetab_index): New, emit a symtypetab index.
	(ctf_serialize): Call them, emitting suitably sorted symtypetab
	sections and indexes.  Set suitable header flags.  Copy over new
	fields.
	* ctf-hash.c (ctf_dynhash_sort_by_name): New, used to impose an
	order on symtypetab index sections.
	* ctf-link.c (ctf_add_type_mapping): Delete erroneous comment
	relating to code that was never committed.
	(ctf_link_one_variable): Improve variable name.
	(check_sym): New, symtypetab analogue of check_variable.
	(ctf_link_deduplicating_one_symtypetab): New.
	(ctf_link_deduplicating_syms): Likewise.
	(ctf_link_deduplicating): Call them.
	(ctf_link_deduplicating_per_cu): Note that we don't call them in
	this case (yet).
	(ctf_link_add_strtab): Set the error on the fp correctly.
	(ctf_link_add_linker_symbol): New (no longer a do-nothing stub), add
	a linker symbol to the in-flight list.
	(ctf_link_shuffle_syms): New (no longer a do-nothing stub), turn the
	in-flight list into a mapping we can use, now its names are
	resolvable in the external strtab.
	* ctf-string.c (ctf_str_rollback_atom): Don't roll back atoms with
	external strtab offsets.
	(ctf_str_rollback): Adjust comment.
	(ctf_str_write_strtab): Migrate ctf_syn_ext_strtab population from
	writeout time...
	(ctf_str_add_external): ... to string addition time.
	* ctf-lookup.c (ctf_lookup_var_key_t): Rename to...
	(ctf_lookup_idx_key_t): ... this, now we use it for syms too.
	<clik_names>: New member, a name table.
	(ctf_lookup_var): Adjust accordingly.
	(ctf_lookup_variable): Likewise.
	(ctf_lookup_by_id): Shuffle further up in the file.
	(ctf_symidx_sort_arg_cb): New, callback for...
	(sort_symidx_by_name): ... this new function to sort a symidx
	found to be unsorted (likely originating from the compiler).
	(ctf_symidx_sort): New, sort a symidx.
	(ctf_lookup_symbol_name): Support dynamic symbols with indexes
	provided by the linker.  Use ctf_link_sym_t, not Elf64_Sym.
	Check the parent if a child lookup fails.
	(ctf_lookup_by_symbol): Likewise.  Work for function symbols too.
	(ctf_symbol_next): New, iterate over symbols with types (without
	sorting).
	(ctf_lookup_idx_name): New, bsearch for symbol names in indexes.
	(ctf_try_lookup_indexed): New, attempt an indexed lookup.
	(ctf_func_info): Reimplement in terms of ctf_lookup_by_symbol.
	(ctf_func_args): Likewise.
	(ctf_get_dict): Move...
	* ctf-types.c (ctf_get_dict): ... here.
	* ctf-util.c (ctf_sym_to_elf64): Re-express as...
	(ctf_elf64_to_link_sym): ... this.  Add new st_symidx field, and
	st_nameidx_set (always 0, so st_nameidx can be ignored).  Look in
	the ELF strtab for names.
	(ctf_elf32_to_link_sym): Likewise, for Elf32_Sym.
	(ctf_next_destroy): Destroy ctf_next_t.u.ctn_next if need be.
	* libctf.ver: Add ctf_symbol_next, ctf_add_objt_sym and
	ctf_add_func_sym.
2020-11-20 13:34:08 +00:00

791 lines
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/* Implementation header.
Copyright (C) 2019-2020 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/>. */
#ifndef _CTF_IMPL_H
#define _CTF_IMPL_H
#include "config.h"
#include <errno.h>
#include <sys/param.h>
#include "ctf-decls.h"
#include <ctf-api.h>
#include "ctf-sha1.h"
#include <sys/types.h>
#include <stdlib.h>
#include <stdarg.h>
#include <stdio.h>
#include <stdint.h>
#include <limits.h>
#include <ctype.h>
#include <elf.h>
#include <bfd.h>
#include "hashtab.h"
#include "ctf-intl.h"
#ifdef __cplusplus
extern "C"
{
#endif
/* Tuning. */
/* The proportion of symtypetab entries which must be pads before we consider it
worthwhile to emit a symtypetab section as an index. Indexes cost time to
look up, but save space all told. Do not set to 1, since this will cause
indexes to be eschewed completely, even in child dicts, at considerable space
cost. */
#define CTF_INDEX_PAD_THRESHOLD .75
/* Compiler attributes. */
#if defined (__GNUC__)
/* GCC. We assume that all compilers claiming to be GCC support sufficiently
many GCC attributes that the code below works. If some non-GCC compilers
masquerading as GCC in fact do not implement these attributes, version checks
may be required. */
/* We use the _libctf_*_ pattern to avoid clashes with any future attribute
macros glibc may introduce, which have names of the pattern
__attribute_blah__. */
#define _libctf_printflike_(string_index,first_to_check) \
__attribute__ ((__format__ (__printf__, (string_index), (first_to_check))))
#define _libctf_unlikely_(x) __builtin_expect ((x), 0)
#define _libctf_unused_ __attribute__ ((__unused__))
#define _libctf_malloc_ __attribute__((__malloc__))
#define _libctf_nonnull_ __attribute__((__nonnull__))
#else
#define _libctf_printflike_(string_index,first_to_check)
#define _libctf_unlikely_(x) (x)
#define _libctf_unused_
#define _libctf_malloc_
#define _libctf_nonnull_
#define __extension__
#endif
#if defined (ENABLE_LIBCTF_HASH_DEBUGGING) && !defined (NDEBUG)
#include <assert.h>
#define ctf_assert(fp, expr) (assert (expr), 1)
#else
#define ctf_assert(fp, expr) \
_libctf_unlikely_ (ctf_assert_internal (fp, __FILE__, __LINE__, \
#expr, !!(expr)))
#endif
/* libctf in-memory state. */
typedef struct ctf_fixed_hash ctf_hash_t; /* Private to ctf-hash.c. */
typedef struct ctf_dynhash ctf_dynhash_t; /* Private to ctf-hash.c. */
typedef struct ctf_dynset ctf_dynset_t; /* Private to ctf-hash.c. */
typedef struct ctf_strs
{
const char *cts_strs; /* Base address of string table. */
size_t cts_len; /* Size of string table in bytes. */
} ctf_strs_t;
typedef struct ctf_strs_writable
{
char *cts_strs; /* Base address of string table. */
size_t cts_len; /* Size of string table in bytes. */
} ctf_strs_writable_t;
typedef struct ctf_dmodel
{
const char *ctd_name; /* Data model name. */
int ctd_code; /* Data model code. */
size_t ctd_pointer; /* Size of void * in bytes. */
size_t ctd_char; /* Size of char in bytes. */
size_t ctd_short; /* Size of short in bytes. */
size_t ctd_int; /* Size of int in bytes. */
size_t ctd_long; /* Size of long in bytes. */
} ctf_dmodel_t;
typedef struct ctf_names
{
ctf_hash_t *ctn_readonly; /* Hash table when readonly. */
ctf_dynhash_t *ctn_writable; /* Hash table when writable. */
} ctf_names_t;
typedef struct ctf_lookup
{
const char *ctl_prefix; /* String prefix for this lookup. */
size_t ctl_len; /* Length of prefix string in bytes. */
ctf_names_t *ctl_hash; /* Pointer to hash table for lookup. */
} ctf_lookup_t;
typedef struct ctf_dictops
{
uint32_t (*ctfo_get_kind) (uint32_t);
uint32_t (*ctfo_get_root) (uint32_t);
uint32_t (*ctfo_get_vlen) (uint32_t);
ssize_t (*ctfo_get_ctt_size) (const ctf_dict_t *, const ctf_type_t *,
ssize_t *, ssize_t *);
ssize_t (*ctfo_get_vbytes) (ctf_dict_t *, unsigned short, ssize_t, size_t);
} ctf_dictops_t;
typedef struct ctf_list
{
struct ctf_list *l_prev; /* Previous pointer or tail pointer. */
struct ctf_list *l_next; /* Next pointer or head pointer. */
} ctf_list_t;
typedef enum
{
CTF_PREC_BASE,
CTF_PREC_POINTER,
CTF_PREC_ARRAY,
CTF_PREC_FUNCTION,
CTF_PREC_MAX
} ctf_decl_prec_t;
typedef struct ctf_decl_node
{
ctf_list_t cd_list; /* Linked list pointers. */
ctf_id_t cd_type; /* Type identifier. */
uint32_t cd_kind; /* Type kind. */
uint32_t cd_n; /* Type dimension if array. */
} ctf_decl_node_t;
typedef struct ctf_decl
{
ctf_list_t cd_nodes[CTF_PREC_MAX]; /* Declaration node stacks. */
int cd_order[CTF_PREC_MAX]; /* Storage order of decls. */
ctf_decl_prec_t cd_qualp; /* Qualifier precision. */
ctf_decl_prec_t cd_ordp; /* Ordered precision. */
char *cd_buf; /* Buffer for output. */
int cd_err; /* Saved error value. */
int cd_enomem; /* Nonzero if OOM during printing. */
} ctf_decl_t;
typedef struct ctf_dmdef
{
ctf_list_t dmd_list; /* List forward/back pointers. */
char *dmd_name; /* Name of this member. */
ctf_id_t dmd_type; /* Type of this member (for sou). */
unsigned long dmd_offset; /* Offset of this member in bits (for sou). */
int dmd_value; /* Value of this member (for enum). */
} ctf_dmdef_t;
typedef struct ctf_dtdef
{
ctf_list_t dtd_list; /* List forward/back pointers. */
ctf_id_t dtd_type; /* Type identifier for this definition. */
ctf_type_t dtd_data; /* Type node, including name. */
union
{
ctf_list_t dtu_members; /* struct, union, or enum */
ctf_arinfo_t dtu_arr; /* array */
ctf_encoding_t dtu_enc; /* integer or float */
uint32_t *dtu_argv; /* function */
ctf_slice_t dtu_slice; /* slice */
} dtd_u;
} ctf_dtdef_t;
typedef struct ctf_dvdef
{
ctf_list_t dvd_list; /* List forward/back pointers. */
char *dvd_name; /* Name associated with variable. */
ctf_id_t dvd_type; /* Type of variable. */
unsigned long dvd_snapshots; /* Snapshot count when inserted. */
} ctf_dvdef_t;
typedef struct ctf_err_warning
{
ctf_list_t cew_list; /* List forward/back pointers. */
int cew_is_warning; /* 1 if warning, 0 if error. */
char *cew_text; /* Error/warning text. */
} ctf_err_warning_t;
/* Atoms associate strings with a list of the CTF items that reference that
string, so that ctf_update() can instantiate all the strings using the
ctf_str_atoms and then reassociate them with the real string later.
Strings can be interned into ctf_str_atom without having refs associated
with them, for values that are returned to callers, etc. Items are only
removed from this table on ctf_close(), but on every ctf_update(), all the
csa_refs in all entries are purged. */
typedef struct ctf_str_atom
{
const char *csa_str; /* Backpointer to string (hash key). */
ctf_list_t csa_refs; /* This string's refs. */
uint32_t csa_offset; /* Strtab offset, if any. */
uint32_t csa_external_offset; /* External strtab offset, if any. */
unsigned long csa_snapshot_id; /* Snapshot ID at time of creation. */
} ctf_str_atom_t;
/* The refs of a single string in the atoms table. */
typedef struct ctf_str_atom_ref
{
ctf_list_t caf_list; /* List forward/back pointers. */
uint32_t *caf_ref; /* A single ref to this string. */
} ctf_str_atom_ref_t;
/* A single linker-provided symbol, during symbol addition, possibly before we
have been given external strtab refs. */
typedef struct ctf_in_flight_dynsym
{
ctf_list_t cid_list; /* List forward/back pointers. */
ctf_link_sym_t cid_sym; /* The linker-known symbol. */
} ctf_in_flight_dynsym_t;
/* The structure used as the key in a ctf_link_type_mapping. The value is a
type index, not a type ID. */
typedef struct ctf_link_type_key
{
ctf_dict_t *cltk_fp;
ctf_id_t cltk_idx;
} ctf_link_type_key_t;
/* The structure used as the key in a cd_id_to_dict_t on 32-bit platforms. */
typedef struct ctf_type_id_key
{
int ctii_input_num;
ctf_id_t ctii_type;
} ctf_type_id_key_t;
/* Deduplicator state.
The dedup state below uses three terms consistently. A "hash" is a
ctf_dynhash_t; a "hash value" is the hash value of a type as returned by
ctf_dedup_hash_type; a "global type ID" or "global ID" is a packed-together
reference to a single ctf_dict_t (by array index in an array of inputs) and
ctf_id_t, i.e. a single instance of some hash value in some input.
The deduplication algorithm takes a bunch of inputs and yields a single
shared "output" and possibly many outputs corresponding to individual inputs
that still contain types after sharing of unconflicted types. Almost all
deduplicator state is stored in the struct ctf_dedup in the output, though a
(very) few things are stored in inputs for simplicity's sake, usually if they
are linking together things within the scope of a single TU.
Flushed at the end of every ctf_dedup run. */
typedef struct ctf_dedup
{
/* The CTF linker flags in force for this dedup run. */
int cd_link_flags;
/* On 32-bit platforms only, a hash of global type IDs, in the form of
a ctf_link_type_id_key_t. */
ctf_dynhash_t *cd_id_to_dict_t;
/* Atoms tables of decorated names: maps undecorated name to decorated name.
(The actual allocations are in the CTF dict for the former and the real
atoms table for the latter). Uses the same namespaces as ctf_lookups,
below, but has no need for null-termination. */
ctf_dynhash_t *cd_decorated_names[4];
/* Map type names to a hash from type hash value -> number of times each value
has appeared. */
ctf_dynhash_t *cd_name_counts;
/* Map global type IDs to type hash values. Used to determine if types are
already hashed without having to recompute their hash values again, and to
link types together at later stages. Forwards that are peeked through to
structs and unions are not represented in here, so lookups that might be
such a type (in practice, all lookups) must go via cd_replaced_types first
to take this into account. Discarded before each rehashing. */
ctf_dynhash_t *cd_type_hashes;
/* Maps from the names of structs/unions/enums to a a single GID which is the
only appearance of that type in any input: if it appears in more than one
input, a value which is a GID with an input_num of -1 appears. Used in
share-duplicated link mode link modes to determine whether structs/unions
can be cited from multiple TUs. Only populated in that link mode. */
ctf_dynhash_t *cd_struct_origin;
/* Maps type hash values to a set of hash values of the types that cite them:
i.e., pointing backwards up the type graph. Used for recursive conflict
marking. Citations from tagged structures, unions, and forwards do not
appear in this graph. */
ctf_dynhash_t *cd_citers;
/* Maps type hash values to input global type IDs. The value is a set (a
hash) of global type IDs. Discarded before each rehashing. The result of
the ctf_dedup function. */
ctf_dynhash_t *cd_output_mapping;
/* A map giving the GID of the first appearance of each type for each type
hash value. */
ctf_dynhash_t *cd_output_first_gid;
/* Used to ensure that we never try to map a single type ID to more than one
hash. */
ctf_dynhash_t *cd_output_mapping_guard;
/* Maps the global type IDs of structures in input TUs whose members still
need emission to the global type ID of the already-emitted target type
(which has no members yet) in the appropriate target. Uniquely, the latter
ID represents a *target* ID (i.e. the cd_output_mapping of some specified
input): we encode the shared (parent) dict with an ID of -1. */
ctf_dynhash_t *cd_emission_struct_members;
/* A set (a hash) of hash values of conflicting types. */
ctf_dynset_t *cd_conflicting_types;
/* Maps type hashes to ctf_id_t's in this dictionary. Populated only at
emission time, in the dictionary where emission is taking place. */
ctf_dynhash_t *cd_output_emission_hashes;
/* Maps the decorated names of conflicted cross-TU forwards that were forcibly
emitted in this TU to their emitted ctf_id_ts. Populated only at emission
time, in the dictionary where emission is taking place. */
ctf_dynhash_t *cd_output_emission_conflicted_forwards;
/* Points to the output counterpart of this input dictionary, at emission
time. */
ctf_dict_t *cd_output;
} ctf_dedup_t;
/* The ctf_dict is the structure used to represent a CTF dictionary to library
clients, who see it only as an opaque pointer. Modifications can therefore
be made freely to this structure without regard to client versioning. The
ctf_dict_t typedef appears in <ctf-api.h> and declares a forward tag.
(A ctf_file_t typedef also appears there, for historical reasons.)
NOTE: ctf_serialize() requires that everything inside of ctf_dict either be
an immediate value, a pointer to dynamically allocated data *outside* of the
ctf_dict itself, or a pointer to statically allocated data. If you add a
pointer to ctf_dict that points to something within the ctf_dict itself, you
must make corresponding changes to ctf_serialize(). */
struct ctf_dict
{
const ctf_dictops_t *ctf_dictops; /* Version-specific dict operations. */
struct ctf_header *ctf_header; /* The header from this CTF dict. */
unsigned char ctf_openflags; /* Flags the dict had when opened. */
ctf_sect_t ctf_data; /* CTF data from object file. */
ctf_sect_t ctf_symtab; /* Symbol table from object file. */
ctf_sect_t ctf_strtab; /* String table from object file. */
ctf_dynhash_t *ctf_prov_strtab; /* Maps provisional-strtab offsets
to names. */
ctf_dynhash_t *ctf_syn_ext_strtab; /* Maps ext-strtab offsets to names. */
void *ctf_data_mmapped; /* CTF data we mmapped, to free later. */
size_t ctf_data_mmapped_len; /* Length of CTF data we mmapped. */
ctf_names_t ctf_structs; /* Hash table of struct types. */
ctf_names_t ctf_unions; /* Hash table of union types. */
ctf_names_t ctf_enums; /* Hash table of enum types. */
ctf_names_t ctf_names; /* Hash table of remaining type names. */
ctf_lookup_t ctf_lookups[5]; /* Pointers to nametabs for name lookup. */
ctf_strs_t ctf_str[2]; /* Array of string table base and bounds. */
ctf_dynhash_t *ctf_str_atoms; /* Hash table of ctf_str_atoms_t. */
uint64_t ctf_str_num_refs; /* Number of refs to cts_str_atoms. */
uint32_t ctf_str_prov_offset; /* Latest provisional offset assigned so far. */
unsigned char *ctf_base; /* CTF file pointer. */
unsigned char *ctf_dynbase; /* Freeable CTF file pointer. */
unsigned char *ctf_buf; /* Uncompressed CTF data buffer. */
size_t ctf_size; /* Size of CTF header + uncompressed data. */
uint32_t *ctf_sxlate; /* Translation table for unindexed symtypetab
entries. */
unsigned long ctf_nsyms; /* Number of entries in symtab xlate table. */
uint32_t *ctf_txlate; /* Translation table for type IDs. */
uint32_t *ctf_ptrtab; /* Translation table for pointer-to lookups. */
size_t ctf_ptrtab_len; /* Num types storable in ptrtab currently. */
uint32_t *ctf_funcidx_names; /* Name of each function symbol in symtypetab
(if indexed). */
uint32_t *ctf_objtidx_names; /* Likewise, for object symbols. */
size_t ctf_nfuncidx; /* Number of funcidx entries. */
uint32_t *ctf_funcidx_sxlate; /* Offsets into funcinfo for a given funcidx. */
uint32_t *ctf_objtidx_sxlate; /* Likewise, for ctf_objtidx. */
size_t ctf_nobjtidx; /* Number of objtidx entries. */
ctf_dynhash_t *ctf_objthash; /* name -> type ID. */
ctf_dynhash_t *ctf_funchash; /* name -> CTF_K_FUNCTION type ID. */
/* The next three are linker-derived state found in ctf_link targets only. */
ctf_dynhash_t *ctf_dynsyms; /* Symbol info from ctf_link_shuffle_syms. */
ctf_link_sym_t **ctf_dynsymidx; /* Indexes ctf_dynsyms by symidx. */
uint32_t ctf_dynsymmax; /* Maximum ctf_dynsym index. */
ctf_list_t ctf_in_flight_dynsyms; /* Dynsyms during accumulation. */
struct ctf_varent *ctf_vars; /* Sorted variable->type mapping. */
unsigned long ctf_nvars; /* Number of variables in ctf_vars. */
unsigned long ctf_typemax; /* Maximum valid type ID number. */
const ctf_dmodel_t *ctf_dmodel; /* Data model pointer (see above). */
const char *ctf_cuname; /* Compilation unit name (if any). */
char *ctf_dyncuname; /* Dynamically allocated name of CU. */
struct ctf_dict *ctf_parent; /* Parent CTF dict (if any). */
int ctf_parent_unreffed; /* Parent set by ctf_import_unref? */
const char *ctf_parlabel; /* Label in parent dict (if any). */
const char *ctf_parname; /* Basename of parent (if any). */
char *ctf_dynparname; /* Dynamically allocated name of parent. */
uint32_t ctf_parmax; /* Highest type ID of a parent type. */
uint32_t ctf_refcnt; /* Reference count (for parent links). */
uint32_t ctf_flags; /* Libctf flags (see below). */
int ctf_errno; /* Error code for most recent error. */
int ctf_version; /* CTF data version. */
ctf_dynhash_t *ctf_dthash; /* Hash of dynamic type definitions. */
ctf_list_t ctf_dtdefs; /* List of dynamic type definitions. */
ctf_dynhash_t *ctf_dvhash; /* Hash of dynamic variable mappings. */
ctf_list_t ctf_dvdefs; /* List of dynamic variable definitions. */
unsigned long ctf_dtoldid; /* Oldest id that has been committed. */
unsigned long ctf_snapshots; /* ctf_snapshot() plus ctf_update() count. */
unsigned long ctf_snapshot_lu; /* ctf_snapshot() call count at last update. */
ctf_archive_t *ctf_archive; /* Archive this ctf_dict_t came from. */
ctf_list_t ctf_errs_warnings; /* CTF errors and warnings. */
ctf_dynhash_t *ctf_link_inputs; /* Inputs to this link. */
ctf_dynhash_t *ctf_link_outputs; /* Additional outputs from this link. */
/* Map input types to output types: populated in each output dict.
Key is a ctf_link_type_key_t: value is a type ID. Used by
nondeduplicating links and ad-hoc ctf_add_type calls only. */
ctf_dynhash_t *ctf_link_type_mapping;
/* Map input CU names to output CTF dict names: populated in the top-level
output dict.
Key and value are dynamically-allocated strings. */
ctf_dynhash_t *ctf_link_in_cu_mapping;
/* Map output CTF dict names to input CU names: populated in the top-level
output dict. A hash of string to hash (set) of strings. Key and
individual value members are shared with ctf_link_in_cu_mapping. */
ctf_dynhash_t *ctf_link_out_cu_mapping;
/* CTF linker flags. */
int ctf_link_flags;
/* Allow the caller to change the name of link archive members. */
ctf_link_memb_name_changer_f *ctf_link_memb_name_changer;
void *ctf_link_memb_name_changer_arg; /* Argument for it. */
/* Allow the caller to filter out variables they don't care about. */
ctf_link_variable_filter_f *ctf_link_variable_filter;
void *ctf_link_variable_filter_arg; /* Argument for it. */
ctf_dynhash_t *ctf_add_processing; /* Types ctf_add_type is working on now. */
/* Atoms table for dedup string storage. All strings in the ctf_dedup_t are
stored here. Only the _alloc copy is allocated or freed: the
ctf_dedup_atoms may be pointed to some other CTF dict, to share its atoms.
We keep the atoms table outside the ctf_dedup so that atoms can be
preserved across multiple similar links, such as when doing cu-mapped
links. */
ctf_dynset_t *ctf_dedup_atoms;
ctf_dynset_t *ctf_dedup_atoms_alloc;
ctf_dedup_t ctf_dedup; /* Deduplicator state. */
char *ctf_tmp_typeslice; /* Storage for slicing up type names. */
size_t ctf_tmp_typeslicelen; /* Size of the typeslice. */
void *ctf_specific; /* Data for ctf_get/setspecific(). */
};
/* An abstraction over both a ctf_dict_t and a ctf_archive_t. */
struct ctf_archive_internal
{
int ctfi_is_archive;
int ctfi_unmap_on_close;
ctf_dict_t *ctfi_dict;
struct ctf_archive *ctfi_archive;
ctf_sect_t ctfi_symsect;
ctf_sect_t ctfi_strsect;
int ctfi_free_symsect;
int ctfi_free_strsect;
void *ctfi_data;
bfd *ctfi_abfd; /* Optional source of section data. */
void (*ctfi_bfd_close) (struct ctf_archive_internal *);
};
/* Iterator state for the *_next() functions. */
/* A single hash key/value pair. */
typedef struct ctf_next_hkv
{
void *hkv_key;
void *hkv_value;
} ctf_next_hkv_t;
struct ctf_next
{
void (*ctn_iter_fun) (void);
ctf_id_t ctn_type;
ssize_t ctn_size;
ssize_t ctn_increment;
uint32_t ctn_n;
/* We can save space on this side of things by noting that a dictionary is
either dynamic or not, as a whole, and a given iterator can only iterate
over one kind of thing at once: so we can overlap the DTD and non-DTD
members, and the structure, variable and enum members, etc.
Some of the _next iterators actually thunk down to another _next iterator
themselves, so one of the options in here is a _next iterator! */
union
{
const ctf_member_t *ctn_mp;
const ctf_lmember_t *ctn_lmp;
const ctf_dmdef_t *ctn_dmd;
const ctf_enum_t *ctn_en;
const ctf_dvdef_t *ctn_dvd;
ctf_next_t *ctn_next;
ctf_next_hkv_t *ctn_sorted_hkv;
void **ctn_hash_slot;
} u;
/* This union is of various sorts of dict we can iterate over:
currently dictionaries and archives, dynhashes, and dynsets. */
union
{
const ctf_dict_t *ctn_fp;
const ctf_archive_t *ctn_arc;
const ctf_dynhash_t *ctn_h;
const ctf_dynset_t *ctn_s;
} cu;
};
/* Return x rounded up to an alignment boundary.
eg, P2ROUNDUP(0x1234, 0x100) == 0x1300 (0x13*align)
eg, P2ROUNDUP(0x5600, 0x100) == 0x5600 (0x56*align) */
#define P2ROUNDUP(x, align) (-(-(x) & -(align)))
/* * If an offs is not aligned already then round it up and align it. */
#define LCTF_ALIGN_OFFS(offs, align) ((offs + (align - 1)) & ~(align - 1))
#define LCTF_TYPE_ISPARENT(fp, id) ((id) <= fp->ctf_parmax)
#define LCTF_TYPE_ISCHILD(fp, id) ((id) > fp->ctf_parmax)
#define LCTF_TYPE_TO_INDEX(fp, id) ((id) & (fp->ctf_parmax))
#define LCTF_INDEX_TO_TYPE(fp, id, child) (child ? ((id) | (fp->ctf_parmax+1)) : \
(id))
#define LCTF_INDEX_TO_TYPEPTR(fp, i) \
((fp->ctf_flags & LCTF_RDWR) ? \
&(ctf_dtd_lookup (fp, LCTF_INDEX_TO_TYPE \
(fp, i, fp->ctf_flags & LCTF_CHILD))->dtd_data) : \
(ctf_type_t *)((uintptr_t)(fp)->ctf_buf + (fp)->ctf_txlate[(i)]))
#define LCTF_INFO_KIND(fp, info) ((fp)->ctf_dictops->ctfo_get_kind(info))
#define LCTF_INFO_ISROOT(fp, info) ((fp)->ctf_dictops->ctfo_get_root(info))
#define LCTF_INFO_VLEN(fp, info) ((fp)->ctf_dictops->ctfo_get_vlen(info))
#define LCTF_VBYTES(fp, kind, size, vlen) \
((fp)->ctf_dictops->ctfo_get_vbytes(fp, kind, size, vlen))
#define LCTF_CHILD 0x0001 /* CTF dict is a child. */
#define LCTF_RDWR 0x0002 /* CTF dict is writable. */
#define LCTF_DIRTY 0x0004 /* CTF dict has been modified. */
extern ctf_names_t *ctf_name_table (ctf_dict_t *, int);
extern const ctf_type_t *ctf_lookup_by_id (ctf_dict_t **, ctf_id_t);
extern ctf_id_t ctf_lookup_by_rawname (ctf_dict_t *, int, const char *);
extern ctf_id_t ctf_lookup_by_rawhash (ctf_dict_t *, ctf_names_t *, const char *);
extern void ctf_set_ctl_hashes (ctf_dict_t *);
extern int ctf_symtab_skippable (ctf_link_sym_t *sym);
extern int ctf_add_funcobjt_sym (ctf_dict_t *, int is_function,
const char *, ctf_id_t);
extern ctf_dict_t *ctf_get_dict (ctf_dict_t *fp, ctf_id_t type);
typedef unsigned int (*ctf_hash_fun) (const void *ptr);
extern unsigned int ctf_hash_integer (const void *ptr);
extern unsigned int ctf_hash_string (const void *ptr);
extern unsigned int ctf_hash_type_key (const void *ptr);
extern unsigned int ctf_hash_type_id_key (const void *ptr);
typedef int (*ctf_hash_eq_fun) (const void *, const void *);
extern int ctf_hash_eq_integer (const void *, const void *);
extern int ctf_hash_eq_string (const void *, const void *);
extern int ctf_hash_eq_type_key (const void *, const void *);
extern int ctf_hash_eq_type_id_key (const void *, const void *);
extern int ctf_dynset_eq_string (const void *, const void *);
typedef void (*ctf_hash_free_fun) (void *);
typedef void (*ctf_hash_iter_f) (void *key, void *value, void *arg);
typedef int (*ctf_hash_iter_remove_f) (void *key, void *value, void *arg);
typedef int (*ctf_hash_iter_find_f) (void *key, void *value, void *arg);
typedef int (*ctf_hash_sort_f) (const ctf_next_hkv_t *, const ctf_next_hkv_t *,
void *arg);
extern ctf_hash_t *ctf_hash_create (unsigned long, ctf_hash_fun, ctf_hash_eq_fun);
extern int ctf_hash_insert_type (ctf_hash_t *, ctf_dict_t *, uint32_t, uint32_t);
extern int ctf_hash_define_type (ctf_hash_t *, ctf_dict_t *, uint32_t, uint32_t);
extern ctf_id_t ctf_hash_lookup_type (ctf_hash_t *, ctf_dict_t *, const char *);
extern uint32_t ctf_hash_size (const ctf_hash_t *);
extern void ctf_hash_destroy (ctf_hash_t *);
extern ctf_dynhash_t *ctf_dynhash_create (ctf_hash_fun, ctf_hash_eq_fun,
ctf_hash_free_fun, ctf_hash_free_fun);
extern int ctf_dynhash_insert (ctf_dynhash_t *, void *, void *);
extern void ctf_dynhash_remove (ctf_dynhash_t *, const void *);
extern size_t ctf_dynhash_elements (ctf_dynhash_t *);
extern void ctf_dynhash_empty (ctf_dynhash_t *);
extern void *ctf_dynhash_lookup (ctf_dynhash_t *, const void *);
extern int ctf_dynhash_lookup_kv (ctf_dynhash_t *, const void *key,
const void **orig_key, void **value);
extern void ctf_dynhash_destroy (ctf_dynhash_t *);
extern void ctf_dynhash_iter (ctf_dynhash_t *, ctf_hash_iter_f, void *);
extern void ctf_dynhash_iter_remove (ctf_dynhash_t *, ctf_hash_iter_remove_f,
void *);
extern void *ctf_dynhash_iter_find (ctf_dynhash_t *, ctf_hash_iter_find_f,
void *);
extern int ctf_dynhash_sort_by_name (const ctf_next_hkv_t *,
const ctf_next_hkv_t *,
void * _libctf_unused_);
extern int ctf_dynhash_next (ctf_dynhash_t *, ctf_next_t **,
void **key, void **value);
extern int ctf_dynhash_next_sorted (ctf_dynhash_t *, ctf_next_t **,
void **key, void **value, ctf_hash_sort_f,
void *);
extern ctf_dynset_t *ctf_dynset_create (htab_hash, htab_eq, ctf_hash_free_fun);
extern int ctf_dynset_insert (ctf_dynset_t *, void *);
extern void ctf_dynset_remove (ctf_dynset_t *, const void *);
extern void ctf_dynset_destroy (ctf_dynset_t *);
extern void *ctf_dynset_lookup (ctf_dynset_t *, const void *);
extern int ctf_dynset_exists (ctf_dynset_t *, const void *key,
const void **orig_key);
extern int ctf_dynset_next (ctf_dynset_t *, ctf_next_t **, void **key);
extern void *ctf_dynset_lookup_any (ctf_dynset_t *);
extern void ctf_sha1_init (ctf_sha1_t *);
extern void ctf_sha1_add (ctf_sha1_t *, const void *, size_t);
extern char *ctf_sha1_fini (ctf_sha1_t *, char *);
#define ctf_list_prev(elem) ((void *)(((ctf_list_t *)(elem))->l_prev))
#define ctf_list_next(elem) ((void *)(((ctf_list_t *)(elem))->l_next))
extern void ctf_list_append (ctf_list_t *, void *);
extern void ctf_list_prepend (ctf_list_t *, void *);
extern void ctf_list_delete (ctf_list_t *, void *);
extern void ctf_list_splice (ctf_list_t *, ctf_list_t *);
extern int ctf_list_empty_p (ctf_list_t *lp);
extern int ctf_dtd_insert (ctf_dict_t *, ctf_dtdef_t *, int flag, int kind);
extern void ctf_dtd_delete (ctf_dict_t *, ctf_dtdef_t *);
extern ctf_dtdef_t *ctf_dtd_lookup (const ctf_dict_t *, ctf_id_t);
extern ctf_dtdef_t *ctf_dynamic_type (const ctf_dict_t *, ctf_id_t);
extern int ctf_dvd_insert (ctf_dict_t *, ctf_dvdef_t *);
extern void ctf_dvd_delete (ctf_dict_t *, ctf_dvdef_t *);
extern ctf_dvdef_t *ctf_dvd_lookup (const ctf_dict_t *, const char *);
extern ctf_id_t ctf_add_encoded (ctf_dict_t *, uint32_t, const char *,
const ctf_encoding_t *, uint32_t kind);
extern ctf_id_t ctf_add_reftype (ctf_dict_t *, uint32_t, ctf_id_t,
uint32_t kind);
extern void ctf_add_type_mapping (ctf_dict_t *src_fp, ctf_id_t src_type,
ctf_dict_t *dst_fp, ctf_id_t dst_type);
extern ctf_id_t ctf_type_mapping (ctf_dict_t *src_fp, ctf_id_t src_type,
ctf_dict_t **dst_fp);
extern int ctf_dedup_atoms_init (ctf_dict_t *);
extern int ctf_dedup (ctf_dict_t *, ctf_dict_t **, uint32_t ninputs,
uint32_t *parents, int cu_mapped);
extern void ctf_dedup_fini (ctf_dict_t *, ctf_dict_t **, uint32_t);
extern ctf_dict_t **ctf_dedup_emit (ctf_dict_t *, ctf_dict_t **,
uint32_t ninputs, uint32_t *parents,
uint32_t *noutputs, int cu_mapped);
extern void ctf_decl_init (ctf_decl_t *);
extern void ctf_decl_fini (ctf_decl_t *);
extern void ctf_decl_push (ctf_decl_t *, ctf_dict_t *, ctf_id_t);
_libctf_printflike_ (2, 3)
extern void ctf_decl_sprintf (ctf_decl_t *, const char *, ...);
extern char *ctf_decl_buf (ctf_decl_t *cd);
extern const char *ctf_strptr (ctf_dict_t *, uint32_t);
extern const char *ctf_strraw (ctf_dict_t *, uint32_t);
extern const char *ctf_strraw_explicit (ctf_dict_t *, uint32_t,
ctf_strs_t *);
extern int ctf_str_create_atoms (ctf_dict_t *);
extern void ctf_str_free_atoms (ctf_dict_t *);
extern uint32_t ctf_str_add (ctf_dict_t *, const char *);
extern uint32_t ctf_str_add_ref (ctf_dict_t *, const char *, uint32_t *ref);
extern int ctf_str_add_external (ctf_dict_t *, const char *, uint32_t offset);
extern void ctf_str_remove_ref (ctf_dict_t *, const char *, uint32_t *ref);
extern void ctf_str_rollback (ctf_dict_t *, ctf_snapshot_id_t);
extern void ctf_str_purge_refs (ctf_dict_t *);
extern ctf_strs_writable_t ctf_str_write_strtab (ctf_dict_t *);
extern struct ctf_archive_internal *
ctf_new_archive_internal (int is_archive, int unmap_on_close,
struct ctf_archive *, ctf_dict_t *,
const ctf_sect_t *symsect,
const ctf_sect_t *strsect, int *errp);
extern struct ctf_archive *ctf_arc_open_internal (const char *, int *);
extern void ctf_arc_close_internal (struct ctf_archive *);
extern const ctf_preamble_t *ctf_arc_bufpreamble (const ctf_sect_t *);
extern void *ctf_set_open_errno (int *, int);
extern unsigned long ctf_set_errno (ctf_dict_t *, int);
extern ctf_dict_t *ctf_simple_open_internal (const char *, size_t, const char *,
size_t, size_t,
const char *, size_t,
ctf_dynhash_t *, int, int *);
extern ctf_dict_t *ctf_bufopen_internal (const ctf_sect_t *, const ctf_sect_t *,
const ctf_sect_t *, ctf_dynhash_t *,
int, int *);
extern int ctf_import_unref (ctf_dict_t *fp, ctf_dict_t *pfp);
extern int ctf_serialize (ctf_dict_t *);
_libctf_malloc_
extern void *ctf_mmap (size_t length, size_t offset, int fd);
extern void ctf_munmap (void *, size_t);
extern ssize_t ctf_pread (int fd, void *buf, ssize_t count, off_t offset);
extern void *ctf_realloc (ctf_dict_t *, void *, size_t);
extern char *ctf_str_append (char *, const char *);
extern char *ctf_str_append_noerr (char *, const char *);
extern ctf_id_t ctf_type_resolve_unsliced (ctf_dict_t *, ctf_id_t);
extern int ctf_type_kind_unsliced (ctf_dict_t *, ctf_id_t);
_libctf_printflike_ (1, 2)
extern void ctf_dprintf (const char *, ...);
extern void libctf_init_debug (void);
_libctf_printflike_ (4, 5)
extern void ctf_err_warn (ctf_dict_t *, int is_warning, int err,
const char *, ...);
extern void ctf_err_warn_to_open (ctf_dict_t *);
extern void ctf_assert_fail_internal (ctf_dict_t *, const char *,
size_t, const char *);
extern const char *ctf_link_input_name (ctf_dict_t *);
extern ctf_link_sym_t *ctf_elf32_to_link_sym (ctf_dict_t *fp, ctf_link_sym_t *dst,
const Elf32_Sym *src, uint32_t symidx);
extern ctf_link_sym_t *ctf_elf64_to_link_sym (ctf_dict_t *fp, ctf_link_sym_t *dst,
const Elf64_Sym *src, uint32_t symidx);
extern const char *ctf_lookup_symbol_name (ctf_dict_t *fp, unsigned long symidx);
/* Variables, all underscore-prepended. */
extern const char _CTF_SECTION[]; /* name of CTF ELF section */
extern const char _CTF_NULLSTR[]; /* empty string */
extern int _libctf_version; /* library client version */
extern int _libctf_debug; /* debugging messages enabled */
#include "ctf-inlines.h"
#ifdef __cplusplus
}
#endif
#endif /* _CTF_IMPL_H */
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