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119 Commits

Author SHA1 Message Date
Nick Alcock
99e9ab4828 libctf: adjust foreign-endian byteswapping for v4 
Split into a separate commit because it's not yet really tested.

Callers not yet adjusted.
 2025-04-25 18:07:41 +01:00
Nick Alcock
2ef9554023 libctf: ctf-lookup: support prefixes in ctf_lookup_by_id 
ctf_lookup_by_id now has a new optional suffix argument, which,
if set, returns the suffix of a prefixed type: the ctf_type_t it
returns remains (as ever) the first one in the type (i.e. it
may be a prefix type).  This is most convenient because the prefix
is the ctf_type_t that LCTF_KIND and other LCTF functions taking
ctf_type_t's expect.

Callers not yet adjusted.
 2025-04-25 18:07:41 +01:00
Nick Alcock
a80b903b45 libctf: simplify ctf_txlate 
Before now, this critical internal structure was an array mapping from a
type ID to the type index of the type with that ID.  This was critical for
the old world in which ctf_update() reserialized the entire dict, so things
moved around in memory all the time: but these days, a ctf_type_t * never
moves after creation, so we can just make ctf_txlate an array of ctf_type_t *
and be done with it.

This lets us point type indexes anywhere in memory, not just to entries
in the ctf_buf, which means we can have synthetic ones for various purposes.
And we will.
 2025-04-25 18:07:41 +01:00
Nick Alcock
1d70873382 libctf: dynhash/dynset: a bit of const-correctness 
A pile of dynhash and dynset functions were requiring non-const hashes/sets
unnecessarily.  Fix them.
 2025-04-25 18:07:41 +01:00
Nick Alcock
40aea6c596 libctf: ctf_next_t.ctn_size: make a size_t 
Literally every single user would rather this is a size_t, rather
than an ssize_t.  Change it.
 2025-04-25 18:07:41 +01:00
Nick Alcock
6a4a485c7b libctf: adapt core dictops for v4 and prefix types 
The heart of libctf's reading code is the ctf_dictops_t and the functions it
provides for reading various things no matter what the CTF version in use:
these are called via LCTF_*() macros that translate into calls into the
dictops.

The introduction of prefix types in v4 requires changes here: in particular,
we want the ability to get the type kind of whatever ctf_type_t we are
looking at (the 'unprefixed' kind), as well as the ability to get the type
kind taking prefixes into account: and more generally we want the ability
to both look at a given prefix and look at the type as a whole.  So several
ctf_dictops_t entries are added for this (ctfo_get_prefixed_kind,
ctfo_get_prefixed_vlen).

This means API changes (no callers yet adjusted, it'll happen as we go),
because the existing macros were mostly called with e.g. a ctt_info value
and returned a type kind, while now we need to be called with the actual
ctf_type_t itself, so we can possibly walk beyond it to find the real type
record.  ctfo_get_vbytes needs adjusting for this.

We also add names to most of the ctf_type_t parameters, because suddenly we
can have up to three of them: one relating to the first entry in the type
record (which may be a prefix, usually called 'prefix'), one relating to the
true type record (which may be a suffix, so usually called 'suffix'), and
one possibly relating to some intermediate record if we have multiple
prefixes (usually called 'tp').

There is one horrible special case in here: the vlen of the new
CTF_K_FUNC_LINKAGE kind (equivalent to BTF_KIND_FUNC) is always zero: it
reuses the vlen field to encode the linkage (!).  BTF is rife with ugly
hacks like this.
 2025-04-25 18:07:41 +01:00
Nick Alcock
ab3ad58be9 libctf: don't warn about unused fp in ctf_assert 
When hash debugging is enabled and NDEBUG is not set, ctf_assert()
translates into a true assert().  Don't leave the fp parameter
unused in this case (which can cause compiler errors when -Werror
is also on).
 2025-04-25 18:07:41 +01:00
Nick Alcock
b5d3790c66 libctf: consecutive ctf_id_t assignment 
This change modifies type ID assignment in CTF so that it works like BTF:
rather than flipping the high bit on for types in child dicts, types ascend
directly from IDs in the parent to IDs in the child, without interruption
(so type 0x4 in the parent is immediately followed by 0x5 in all children).

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

So we have to be a litle cleverer.

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

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

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

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

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

Various things are newly forbidden:

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

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

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

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

The ld-ctf tests get a bunch of largely display-based updates: various
tests refer to 0x8... type IDs, which no longer exist, and because the
IDs are shorter all the spacing and alignment has changed.
 2025-03-16 15:25:27 +00:00
Nick Alcock
beccf36b88 libctf: move string deduplication into ctf-archive 
This means that any archive containing dicts can get its strings dedupped
together, rather than only those that are ctf_linked.

(For now, we are still constrained to ctf_linked archives, since fixing that
requires further changes to ctf_dedup_strings: but this gives us the first
half of what is necessary.)

libctf/
	* ctf-link.c (ctf_link_write): Move string dedup into...
	* ctf-archive.c (ctf_arc_preserialize): ... this new function.
	(ctf_arc_write_fd): Call it.
 2025-02-28 15:13:24 +00:00
Nick Alcock
a480362d88 libctf: string: refs rework 
This commit moves provisional (not-yet-serialized) string refs towards the
scheme to be used for CTF IDs in the future.  In particular

 - provisional string offsets now count downwards from just under the
   external string offset space (all bits on but the high bit).  This makes
   it possible to detect an overflowing strtab, and also makes it trivial to
   determine whether any string offset (ref) updates were missed -- where
   before we might get a slightly corrupted or incorrect string, we now get
   a huge high strtab offset corresponding to no string, and an error is
   emitted at read time.

 - refs are emitted at serialization time during the pass through the types.
   They are strictly associated with the newly-written-out buffer: the
   existing opened CTF dict is not changed, though it does still get the new
   strtab so that new refs to the same string can just refer directly to it.
   The provisional strtab hash table that contains these strings is not
   deleted after serialization (because we might serialize again): instead,
   we keep track in the parent of the lowest-yet-used ("latest") provisional
   strtab offset, and any strtab offset above that, but not external
   (high-bit-on) is considered provisional.

   This is sort-of-enforced by moving most of the ref-addition function
   declarations (including ctf_str_add_ref) to a new ctf-ref.h, which is
   not included by ctf-create.c or ctf-open.c.

 - because we don't add refs when adding types, we don't need to handle the
   case where we add things to expanding vlens (enums, struct members) and
   have to realloc() them.  So the entire painful movable refs system can
   just be deleted, along with the ability to remove refs piecemeal at all
   (purging all of them is still possible).  Strings added during type
   addition are added via ctf_str_add(), which adds no refs: the strings are
   picked up at serialization time and refs to their final, serialized
   resting place added.  The DTDs never have any refs in them, and their
   provisional strtab offsets are never updated by the ref system.

This caused several bugs to fall out of the earlier work and get fixed.
In particular, attempts to look up a string in a child dict now search
the parent's provisional strtab too: we add some extra special casing
for the null string so we don't need to worry about deduplication
moving it somewhere other than offset zero.

Finally, the optimization that removes an unreferenced synthetic external
strtab (the record of the strings the linker has told us about, kept around
internally for lookup during late serialization) is faulty: references to a
strtab entry will only produce CTF-level refs if their value might change,
and an external string's offset won't change, so it produces no refs: worse
yet, even if we did get a ref (say, if the string was originally believed
to be internal and only later were we told that the linker knew about it
too), when we serialize a strtab, all its refs are dropped (since they've
been updated and can no longer change); so if we serialized it a second
time, its synthetic external strtab would be considered empty and dropped,
even though the same external strings as before still exist, referencing
it.  We must keep the synthetic external strtab around as long as external
strings exist that reference it, i.e. for the life of the dict.

One benefit of all this: now we're emitting provisional string offsets at
a really high value, it's out of the way of the consecutive, deduplicated
string offsets in child dicts.  So we can drop the constraint that you
cannot add strings to a dict with children, which allows us to add types
freely to parent dicts again.  What you can't do is write that dict out
again: when we serialize, we currently update the dict being serialized
with the updated strtabs: when you write a dict out, its provisional
strings become real strings, and suddenly the offsets would overlap once
more.  But opening a dict and its children, adding to it, and then
writing it out again is rare indeed, and we have a workaround: anyone
wanting to do this can just use ctf_link instead.
 2025-02-28 15:13:24 +00:00
Nick Alcock
97a72b2a35 libctf: create: fix vlen / vbytes confusion 
The initial_vlen parameter to ctf_add_generic is misnamed: it's not the
initial vlen (the initial number of members of a struct, etc), but rather
the initial size of the vlen region.  We have a term for that, vbytes: use
it.

Amazingly this doesn't seem to have caused any bugs to creep in.
 2025-02-28 15:13:24 +00:00
Nick Alcock
dc93d01ff2 libctf: de-macroize LCTF_TYPE_TO_INDEX / LCTF_INDEX_TO_TYPE 
Making these functions is unnecessary right now, but will become much
clearer shortly.

While we're at it, we can drop the third child argument to
LCTF_INDEX_TO_TYPE: it's only used for nontrivial purposes that aren't
literally the same as getting the result from the fp in one place,
in ctf_lookup_by_name_internal, and that place is easily fixed by just
looking in the right dictionary in the first place.
 2025-02-28 15:13:24 +00:00
Nick Alcock
b875301e74 libctf: drop LCTF_TYPE_ISPARENT/LCTF_TYPE_ISCHILD 
Parent/child determination is about to become rather more complex, making a
macro impractical.  Use the ctf_type_isparent/ischild function calls
everywhere and remove the macro.  Make them more const-correct too, to
make them more widely usable.

While we're about it, change several places that hand-implemented
ctf_get_dict() to call it instead, and armour several functions against
the null returns that were always possible in this case (but previously
unprotected-against).
 2025-02-28 15:13:24 +00:00
Nick Alcock
9835747b21 libctf: generalize the ref system 
Despite the removal of the separate movable ref list, the ref system as
a whole is more than complex enough to be worth generalizing now that
we are adding different kinds of ref.

Refs now are lists of uint32_t * which can be updated through the
pointer for all entries in the list and moved to new sites for all
pointers in a given range: they are no longer references to string
offsets in particular and can be references to other uint32_t-sized
things instead (note that ctf_id_t is a typedef to a uint32_t).

ctf-string.c has been adjusted accordingly (the adjustments are tiny,
more or less just turning a bunch of references to atom into
&atom->csa_refs).
 2025-02-28 15:13:24 +00:00
Nick Alcock
21f748e1e3 libctf, string: delete separate movable ref storage again 
This was added last year to let us maintain a backpointer to the movable
refs dynhash in movable ref atoms without spending space for the
backpointer on the majority of (non-movable) refs and also without
causing an atom which had some refs movable and some refs not movable to
dereference unallocated storage when freed.

The backpointer's only purpose was to let us locate the
ctf_str_movable_refs dynhash during item freeing, when we had nothing
but a pointer to the atom being freed.  Now we have a proper freeing
arg, we don't need the backpointer at all: we can just pass a pointer to
the dict in to the atoms dynhash as a freeing arg for the atom freeing
functions, and throw the whole backpointer and separate movable ref list
complexity away.
 2025-02-28 15:13:23 +00:00
Nick Alcock
6a6a3cc9c2 libctf, hash: add support for freeing functions taking an arg 
There are a bunch of places in libctf where the code is complicated
by the fact that freeing a hash key or value requires access to the
dict: more generally, they want an arg pointer to *something*.

But for the sake of being able to use free() as a freeing function,
we can't do this at all times.  We also don't want to bloat up the
hash itself with an arg value unless necessary (in the same way we
already avoid storing the key or value freeing functions unless at
least one of them is specified).

So from the outside this change is simple: add a new
ctf_dynhash_create_arg which takes a new sort of freeing function
which takes an argument.  Internally, we store the arg only when
the key or owner is set, and cast from the one freeing function
to the other iff the arg is non-NULL.  This means it's impossible
to pass a value that may or may not be NULL to the freeing
function, but that's harmless for all current uses, and allows
significant simplifications elsewhere.
 2025-02-28 15:13:23 +00:00
Nick Alcock
4d2d5afa60 libctf: actually deduplicate the strtab 
This commit finally implements strtab deduplication, putting together all
the pieces assembled in the earlier commits.

The magic is entirely localized to ctf_link_write, which preserializes all
the dicts (parent first), and calls ctf_dedup_strings on the parent.

(The error paths get tweaked a bit too.)

Calling ctf_dedup_strings has implications elsewhere: the lifetime rules for
the inputs versus outputs change a bit now that the child output dicts
contain references to the parent dict's atoms table.  We also pre-purge
movable refs from all the deduplicated strings before freeing any of this
because movable refs contain backreferences into the dict they came from,
which means the parent contains references to all the children!  Purging
the refs first makes those references go away so we can free the children
without creating any wild pointers, even temporarily.

There's a new testcase that identifies a regression whereby offset 0 (the
null string) and index 0 (in children now often the parent dict name,
".ctf") got mixed up, leading to anonymous structs and unions getting the
not entirely C-valid name ".ctf" instead.

May other testcases get adjusted to no longer depend on the precise layout
of the strtab.

TODO: add new tests to verify that strings are actually being deduplicated.

libctf/
	* ctf-link.c (ctf_link_write): Deduplicate strings.
	* ctf-open.c (ctf_dict_close): Free refs, then the link outputs,
        then the out cu_mapping, then the inputs, in that order.
        * ctf-string.c (ctf_str_purge_refs): Not static any more.
	* ctf-impl.h: Declare it.

ld/
	* testsuite/ld-ctf/conflicting-cycle-2.A-1.d: Don't depend on
        strtab contents.
	* testsuite/ld-ctf/conflicting-cycle-2.A-2.d: Likewise.
	* testsuite/ld-ctf/conflicting-cycle-2.parent.d: Likewise.
	* testsuite/ld-ctf/conflicting-cycle-3.C-1.d: Likewise.
	* testsuite/ld-ctf/conflicting-cycle-3.C-2.d: Likewise.
	* testsuite/ld-ctf/anonymous-conflicts*: New test.
 2025-02-28 14:47:24 +00:00
Nick Alcock
9daceda796 libctf: dedup: add strtab deduplicator 
This is a pretty simple two-phase process (count duplicates that are
actually going to end up in the strtab and aren't e.g. strings without refs,
strings with external refs etc, and move them into the parent) with one
wrinkle: we sorta-abuse the csa_external_offset field in the deduplicated
child atom (normally used to indicate that this string is located in the ELF
strtab) to indicate that this atom is in the *parent*.  If you think of
"external" as meaning simply "is in some other strtab, we don't care which
one", this still makes enough sense to not need to change the name, I hope.

This is still not called from anywhere, so strings are (still!) not
deduplicated, and none of the dedup machinery added in earlier commits does
anything yet.

libctf/
	* ctf-dedup.c (ctf_dedup_emit_struct_members): Note that strtab
	dedup happens (well) after struct member emission.
	(ctf_dedup_strings): New.
	* ctf-impl.h (ctf_dedup_strings): Declare.
 2025-02-28 14:47:24 +00:00
Nick Alcock
3bec4f1f3c include, libctf: string lookup and writeout of a parent-shared strtab 
The next stage of strtab sharing is actual lookup of strings in such
strtabs, interning of strings in such strtabs and writing out of
such strtabs (but not actually figuring out which strings should
be shared: that's next).

We introduce several new internal ctf_str_* API functions to augment the
existing rather large set: ctf_str_add_copy, which adds a string and always
makes a copy of it (used when deduplicating to stop dedupped strings holding
permanent references on the input dicts), and ctf_str_no_dedup_ref (which
adds a ref to a string while preventing it from ever being deduplicated,
used for header fields like the parent name, which is the same for almost
all child dicts but had still better not be stored in the parent!).

ctf_strraw_explicit, the ultimate underlying "look up a string" function
that backs ctf_strptr et al, gains the ability to automatically find strings
in the parent if the offset is < cth_parent_strlen, and generally make all
offsets parent-relative (so something at offset 1 in the child strlen will
need to be looked up at offset 257 if cth_parent_strlen is 256).  This
suffices to paste together the parent and child from the perspective
of lookup.

We do quite a lot of new checks in here, simply because it's called all over
the place and it's preferable to emit a nice error into the ctf_err_warning
stream if things go wrong.  Among other things this traps cases where you
accidentally added a string to the parent, throwing off all the offsets.
Completely invalid offsets also now add a message to the err_warning
stream.

Insertion of new atoms (the deduplicated entities underlying strings in a
given dict), already a flag-heavy operation, gains more flags, corresponding
to the new ctf_str_add_copy and ctf_str_no_dedup_ref functions: atom
addition also checks the ctf_max_children set by ctf_import and prevents
addition of new atoms to any dicts with ctf_imported children and an
already-serialized strtab.

strtab writeout gains more checks as well: you can't write out a strtab for
a child dict whose parent hasn't been serialized yet (and thus doesn't have
a serialized strtab itself); you can't write it out if the child already
depended on a shared parent strtab and that strtab has changed length.  The
null atom at offset 0 is only written to the parent strtab; and ref updating
changes to look up offsets in the parent's atoms table iff a new
CTF_STR_ATOM_IN_PARENT flag is set on the atom (this will be set by
deduplication to ensure that serializing a dict will update all its refs
properly even though a bunch of them have moved to the parent dict).

None of this actually has any *effect* yet because no string deduplication
is being carried out, and the cth_parent_strlen is still locked at 0.

include/
	* ctf-api.h (_CTF_ERRORS) [ECTF_NOTSERIALIZED]: New.
        (ECTF_NERR): Updated.

libctf/
	* ctf-impl.h (CTF_STR_ATOM_IN_PARENT): New.
	(CTF_STR_ATOM_NO_DEDUP): Likewise.
	(ctf_str_add_no_dedup_ref): New.
	(ctf_str_add_copy): New.
	* ctf-string.c (ctf_strraw_explicit): Look in parents if necessary:
        use parent-relative offsets.
	(ctf_strptr_validate): Avoid duplicating errors.
	(ctf_str_create_atoms): Update comment.
	(CTF_STR_COPY): New.
	(CTF_STR_NO_DEDUP): Likewise.
	(ctf_str_add_ref_internal): Use them, setting the corresponding
        csa_flags, prohibiting addition to serialized parents, and copying
        strings if so requested.
	(ctf_str_add): Turn into a wrapper around...
	(ctf_str_add_flagged): ... this new function.  The offset is now
        parent-relative.
	(ctf_str_add_ref): Likewise.
	(ctf_str_add_movable_ref): Likewise.
	(ctf_str_add_copy): New.
	(ctf_str_add_no_dedup_ref): New.
	(ctf_str_write_strtab): Prohibit writes when the parent has
        changed length or is not serialized.  Only write the null atom
        to parent strtabs.  Chase refs to the parent if necessary.
 2025-02-28 14:47:24 +00:00
Nick Alcock
a14fb397b2 libctf: tear opening and serialization in two 
The next stage in sharing the strtab involves tearing two core parts
of libctf into two pieces.

Large parts of init_static_types, called at open time, involve traversing
the types table and initializing the hashtabs used by the type name lookup
functions and the enumerator conflicting checks.  If the string table is
partly located in the parent dict, this is obviously not going to work: so
split out that code into a new init_static_types_names function (which
also means moving the wrapper around init_static_types that was used
to simplify the enumerator code into being a wrapper around
init_static_types_names instead) and call that from init_static_types
(for parent dicts, and < v4 dicts), and from ctf_import (for v4 dicts).

At the same time as doing this we arrange to set LCTF_NO_STR (recently
introduced) iff this is a v4 child dict with a nonzero cth_parent_strlen:
this then blocks more or less everything that involves string operations
until a ctf_import has actually imported the strtab it depends on.  (No
string oeprations that actually use this have been introduced yet, but
since no string deduplication is happening yet either this is harmless.)

For v4 dicts, at import time we also validate that the cth_parent_strlen has
the same value as the parent's strlen (zero is also a valid value,
indicating a non-shared strtab, as is commonplace in older dicts, dicts
emitted by the compiler, parent dicts etc).  This makes ctf_import more
complex, so we simplify things again by dropping all the repeated code in
the obscure used-only-by-ctf_link ctf_import_unref and turning both into
wrappers around an internal function.  We prohibit repeated ctf_imports
(except of NULL or the same dict repeatedly), and set up some new fields
which will be used later to prevent people from adding strings to parent
dicts with pre-existing serialized strtabs once they have children imported
into them (which would change their string length and corrupt all those
strtabs).

Serialization also needs to be torn in two.  The problem here is that
currently serialization does too much: it emits everything including the
strtab, does things that depend on the strtab being finalized (notably
variable table sorting), and then writes it out.  Much of this emission
itself involves strtab writes, so the strtab is not actually complete until
halfway through ctf_serialize.  But when deduplicating, we want to use
machinery in ctf-link and ctf-dedup to deduplicate the strtab after it is
complete, and only then write it out.

We could do this via having ctf_serialize call some sort of horrible
callback, but it seems much simpler to just cut ctf_serialize in two,
and introduce a new ctf_preserialize which can optionally be called to do
all this "everything but the strtab" work.  (If it's not called,
ctf_serialize calls it itself.)

This means pulling some internal variables out of ctf_serialize into the
ctf_dict_t, and slightly abusing LCTF_NO_STR to mean (in addition to its
"no, you can't do much between opening a child dict and importing its
parent" semantics), "no, you can't do much between calling ctf_preserialize
and ctf_serialize". The requirements of both are not quite identical -- you
definitely can do things that involve string lookups after ctf_preserialize
-- but it serves to stop callers from accidentally adding more types after
the types table has been written out, and that's good enough.
ctf_preserialize isn't public API anyway.

libctf/
	* ctf-impl.h (struct ctf_dict) [ctf_serializing_buf]: New.
        [ctf_serializing_buf_size]: Likewise.
        [ctf_serializing_vars]: Likewise.
        [ctf_serializing_nvars]: Likewise.
        [ctf_max_children]: Likewise.
	(LCTF_PRESERIALIZED): New.
	(ctf_preserialize): New.
	(ctf_depreserialize): New.
	* ctf-open.c (init_static_types): Rename to...
	(init_static_types_names): ... this, wrapping a different
        function.
        (init_static_types_internal): Rename to...
        (init_static_types): ... this, and set LCTF_NO_STR if neecessary.
        Tear out the name-lookup guts into...
	(init_static_types_names_internal): ... this new function. Fix a few
        comment typos.
	(ctf_bufopen): Emphasise that you cannot rely on looking up strings
        at any point in ctf_bufopen any more.
	(ctf_dict_close): Free ctf_serializing_buf.
	(ctf_import): Turn into a wrapper, calling...
	(ctf_import_internal): ... this.  Prohibit repeated ctf_imports of
        different parent dicts, or "unimporting" by setting it back to NULL
        again.  Validate the parent we do import using cth_parent_strlen.
        Call init_static_types_names if the strtab is shared with the
        parent.
	(ctf_import_unref): Turn into a wrapper.
	* ctf-serialize.c (ctf_serialize): Split out everything before
        strtab serialization into...
	(ctf_preserialize): ... this new function.
	(ctf_depreserialize): New, undo preserialization on error.
 2025-02-28 14:47:24 +00:00
Nick Alcock
70d05ab0b2 libctf: add mechanism to prohibit most operations without a strtab 
We are about to add machinery that deduplicates a child dict's strtab
against its parent.  Obviously if you open such a dict but do not import its
parent, all strtab lookups must fail: so add an LCTF_NO_STR flag that is set
in that window and make most operations fail if it's not set.  (Two more
that will be set in future commits are serialization and string lookup
itself.)

Notably, not all symbol lookup is impossible in this window: you can still
look up by symbol index, as long as this dict is not using an indexed
strtypetab (which obviously requires string lookups to get the symbol name).

include/
	* ctf-api.h (_CTF_ERRORS) [ECTF_HASPARENT]: New.
        [ECTF_WRONGPARENT]: Likewise.
	(ECTF_NERR): Update.
        Update comments to note the new limitations on ctf_import et al.

libctf/
	* ctf-impl.h (LCTF_NO_STR): New.
	* ctf-create.c (ctf_rollback): Error out when LCTF_NO_STR.
	(ctf_add_generic): Likewise.
	(ctf_add_struct_sized): Likewise.
	(ctf_add_union_sized): Likewise.
	(ctf_add_enum): Likewise.
	(ctf_add_forward): Likewise.
	(ctf_add_unknown): Likewise.
	(ctf_add_enumerator): Likewise.
	(ctf_add_member_offset): Likewise.
	(ctf_add_variable): Likewise.
	(ctf_add_funcobjt_sym_forced): Likewise.
	(ctf_add_type): Likewise (on either dict).
	* ctf-dump.c (ctf_dump): Likewise.
	* ctf-lookup.c (ctf_lookup_by_name): Likewise.
	(ctf_lookup_variable): Likewise. Likewise.
	(ctf_lookup_enumerator): Likewise.
	(ctf_lookup_enumerator_next): Likewise.
	(ctf_symbol_next): Likewise.
	(ctf_lookup_by_sym_or_name): Likewise, if doing indexed lookups.
	* ctf-types.c (ctf_member_next): Likewise.
	(ctf_enum_next): Likewise.
	(ctf_type_aname): Likewise.
	(ctf_type_name_raw): Likewise.
	(ctf_type_compat): Likewise, for either dict.
	(ctf_member_info): Likewise.
	(ctf_enum_name): Likewise.
	(ctf_enum_value): Likewise.
	(ctf_type_rvisit): Likewise.
	(ctf_variable_next): Note that we don't need to test LCTF_NO_STR.
 2025-02-28 14:47:24 +00:00
Nick Alcock
9a74ab12c8 include, libctf: start work on libctf v4 
This format is a superset of BTF, but for now we just do the minimum to
declare a new file format version, without actually introducing any format
changes.

From now on, we refuse to reserialize CTFv1 dicts: these have a distinct
parent/child boundary which obviously cannot change upon reserialization
(that would change the type IDs): instead, we encoded this by stuffing in
a unique CTF version for such dicts.  We can't do that now we have one
version for all CTFv4 dicts, and testing such old dicts is very hard these
days anyway, and is not automated: so just drop support for writing them out
entirely. (You still *can* write them out, but you have to do a full-blown
ctf_link, which generates an all-new fresh dict and recomputes type IDs as
part of deduplication.)

To prevent this extremely-not-ready format escaping into the wild, add a
new mechanism whereby any format version higher than the new #define
CTF_STABLE_VERSION cannot be serialized unless I_KNOW_LIBCTF_IS_UNSTABLE is
set in the environment.

include/
	* ctf-api.h (_CTF_ERRORS) [ECTF_CTFVERS_NO_SERIALIZE]: New.
        [ECTF_UNSTABLE]: New.
         (ECTF_NERR): Update.
	* ctf.h: Small comment improvements..
        (ctf_header_v3): New, copy of ctf_header.
	(CTF_VERSION_4): New.
	(CTF_VERSION): Now CTF_VERSION_4.
	(CTF_STABLE_VERSION): Still 4, CTF_VERSION_3.

ld/
	* testsuite/ld-ctf/*.d: Update to CTF_VERSION_4.

libctf/
	* ctf-impl.h (LCTF_NO_SERIALIZE): New.
	* ctf-dump.c (ctf_dump_header): Add CTF_VERSION_4.
	* ctf-open.c (ctf_dictops): Likewise.
        (upgrade_header): Rename to...
	(upgrade_header_v2): ... this.
	(upgrade_header_v3): New.
	(upgrade_types): Support upgrading from CTF_VERSION_3.
        Turn on LCTF_NO_SERIALIZE for CTFv1.
	(init_static_types_internal): Upgrade all types tables older than
	* CTF_VERSION_4.
	(ctf_bufopen): Support CTF_VERSION_4: error out if we forget to
	update this switch in future.  Add header upgrading from v3 and
	below.  Improve comments slightly.
	* ctf-serialize.c (ctf_serialize): Block serialization of unstable
	file formats, and of file formats for which LCTF_NO_SERIALIZE is
	turned on (v1).
 2025-02-28 14:47:24 +00:00
Alan Modra
e8e7cf2abe Update year range in copyright notice of binutils files 2025-01-01 18:29:57 +10:30
Nick Alcock
6da9267482 libctf, include: add ctf_dict_set_flag: less enum dup checking by default 
The recent change to detect duplicate enum values and return ECTF_DUPLICATE
when found turns out to perturb a great many callers.  In particular, the
pahole-created kernel BTF has the same problem we historically did, and
gleefully emits duplicated enum constants in profusion.  Handling the
resulting duplicate errors from BTF -> CTF converters reasonably is
unreasonably difficult (it amounts to forcing them to skip some types or
reimplement the deduplicator).

So let's step back a bit.  What we care about mostly is that the
deduplicator treat enums with conflicting enumeration constants as
conflicting types: programs that want to look up enumeration constant ->
value mappings using the new APIs to do so might well want the same checks
to apply to any ctf_add_* operations they carry out (and since they're
*using* the new APIs, added at the same time as this restriction was
imposed, there is likely to be no negative consequence of this).

So we want some way to allow processes that know about duplicate detection
to opt into it, while allowing everyone else to stay clear of it: but we
want ctf_link to get this behaviour even if its caller has opted out.

So add a new concept to the API: dict-wide CTF flags, set via
ctf_dict_set_flag, obtained via ctf_dict_get_flag.  They are not bitflags
but simple arbitrary integers and an on/off value, stored in an unspecified
manner (the one current flag, we translate into an LCTF_* flag value in the
internal ctf_dict ctf_flags word). If you pass in an invalid flag or value
you get a new ECTF_BADFLAG error, so the caller can easily tell whether
flags added in future are valid with a particular libctf or not.

We check this flag in ctf_add_enumerator, and set it around the link
(including on child per-CU dicts).  The newish enumerator-iteration test is
souped up to check the semantics of the flag as well.

The fact that the flag can be set and unset at any time has curious
consequences. You can unset the flag, insert a pile of duplicates, then set
it and expect the new duplicates to be detected, not only by
ctf_add_enumerator but also by ctf_lookup_enumerator.  This means we now
have to maintain the ctf_names and conflicting_enums enum-duplication
tracking as new enums are added, not purely as the dict is opened.
Move that code out of init_static_types_internal and into a new
ctf_track_enumerator function that addition can also call.

(None of this affects the file format or serialization machinery, which has
to be able to handle duplicate enumeration constants no matter what.)

include/
	* ctf-api.h (CTF_ERRORS) [ECTF_BADFLAG]: New.
	(ECTF_NERR): Update.
	(CTF_STRICT_NO_DUP_ENUMERATORS): New flag.
	(ctf_dict_set_flag): New function.
	(ctf_dict_get_flag): Likewise.

libctf/
	* ctf-impl.h (LCTF_STRICT_NO_DUP_ENUMERATORS): New flag.
	(ctf_track_enumerator): Declare.
	* ctf-dedup.c (ctf_dedup_emit_type): Set it.
	* ctf-link.c (ctf_create_per_cu): Likewise.
	(ctf_link_deduplicating_per_cu): Likewise.
	(ctf_link): Likewise.
	(ctf_link_write): Likewise.
	* ctf-subr.c (ctf_dict_set_flag): New function.
	(ctf_dict_get_flag): New function.
	* ctf-open.c (init_static_types_internal): Move enum tracking to...
	* ctf-create.c (ctf_track_enumerator): ... this new function.
	(ctf_add_enumerator): Call it.
	* libctf.ver: Add the new functions.
	* testsuite/libctf-lookup/enumerator-iteration.c: Test them.
 2024-07-31 21:02:05 +01:00
Nick Alcock
36c771b179 libctf: fix CTF dict compression 
Commit 483546ce4f ("libctf: make ctf_serialize() actually serialize")
accidentally broke dict compression.  There were two bugs:

 - ctf_arc_write_one_ctf was still making its own decision about
   whether to compress the dict via direct ctf_size comparison, which is
   unfortunate because now that it no longer calls ctf_serialize itself,
   ctf_size is always zero when it does this: it should let the writing
   functions decide on the threshold, which they contain code to do which is
   simply not used for lack of one trivial wrapper to write to an fd and
   also provide a compression threshold

 - ctf_write_mem, the function underlying all writing as of the commit
   above, was calling zlib's compressBound and avoiding compression if this
   returned a value larger than the input.  Unfortunately compressBound does
   not do a trial compression and determine whether the result is
   compressible: it just adds zlib header sizes to the value passed in, so
   our test would *always* have concluded that the value was incompressible!
   Avoid by simply always compressing if the raw size is larger than the
   threshold: zlib is quite clever enough to avoid actually compressing
   if the data is incompressible.

Add a testcase for this.

libctf/
	* ctf-impl.h (ctf_write_thresholded): New...
	* ctf-serialize.c (ctf_write_thresholded): ... defined here,
        a wrapper around...
        (ctf_write_mem): ... this.  Don't check compressibility.
	(ctf_compress_write): Reimplement as a ctf_write_thresholded
        wrapper.
	(ctf_write): Likewise.
	* ctf-archive.c (arc_write_one_ctf): Just call
        ctf_write_thresholded rather than trying to work out whether
        to compress.
	* testsuite/libctf-writable/ctf-compressed.*: New test.
 2024-07-31 21:02:05 +01:00
Nick Alcock
b404bf7270 libctf, string: split the movable refs out of the ref list 
In commit 149ce5c263 we introduced the concept of "movable" refs,
which are refs that can be moved in batches, to let us maintain valid ref
lists even when adding refs to blocks of memory that can be realloced (which
is any type containing a vlen which can expand, like names contained within
enum or struct members).  Movable refs need a backpointer to the movable
refs dynhash for this dict; since non-movable refs are very common, we tried
to save memory by having a slightly bigger struct for moveable refs with a
backpointer in it, and casting appropriately, indicating which sort of ref
we were dealing with via a flag on the atom.

Unfortunately this doesn't work reliably, because you can perfectly well
have a string ("foo", say) which has both non-movable refs (say, an external
symbol and a variable name) and movable refs (say, a structure member name)
to the same atom.  Indicate which struct we're dealing with with an atom
flag and suddenly you're casting a ctf_str_atom_ref to a
ctf_str_atom_ref_movable (which is bigger) and dereferencing random memory
off the end of it and interpreting it as a backpointer to the movable refs
dynhash.  This is unlikely to work well.

So bite the bullet and split refs into two separate lists, one for movable
refs, one for immovable refs. It means some annoying code duplication, but
there's not very much of it, and it means we can keep the movable refs
hashtab (which in turn means we don't have to do linear searches to find all
relevant refs when moving refs, which in turn means that
structure/union/enum member additions remain amortized O(n) time, not
O(n^2).

Callers can now purge movable and non-movable refs independently of each
other.  We don't use this yet, but a use is coming.

libctf/
	* ctf-impl.h (CTF_STR_ATOM_MOVABLE): Delete.
        (struct ctf_str_atom) [csa_movable_refs]: New.
	(struct ctf_dict): Adjust comment.
	(ctf_str_purge_refs): Add MOVABLE arg.
	* ctf-string.c (ctf_str_purge_movable_atom_refs): Split out of...
        (ctf_str_purge_atom_refs): ... this.
	(ctf_str_free_atom): Call it.
	(ctf_str_purge_one_atom_refs): Likewise.
	(aref_create): Adjust accordingly.
	(ctf_str_move_refs): Likewise.
	(ctf_str_remove_ref): Remove movable refs too, including
	deleting the ref from ctf_str_movable_refs.
	(ctf_str_purge_refs): Add MOVABLE arg.
	(ctf_str_update_refs): Update movable refs.
	(ctf_str_write_strtab): Check, and purge, movable refs.
 2024-07-31 21:02:04 +01:00
Nick Alcock
68720e03f5 libctf, dedup: drop unnecessary arg from ctf_dedup() 
The PARENTS arg is carefully passed down through all the layers of hash
functions and then never used for anything.  (In the distant past it was
used for cycle detection, but the algorithm eventually committed doesn't
need to do cycle detection...)

The PARENTS arg is still used by ctf_dedup_emit(), but even there we can
loosen the requirements and state that you can just leave entries
corresponding to dicts with no parents at zero (which will be useful
in an upcoming commit).

libctf/
	* ctf-dedup.c (ctf_dedup_hash_type): Drop PARENTS arg.
	(ctf_dedup_rhash_type): Likewise.
	(ctf_dedup): Likewise.
	(ctf_dedup_emit_struct_members): Mention what you can do to
        PARENTS entries for parent dicts.
	* ctf-impl.h (ctf_dedup): Adjust accordingly.
	* ctf-link.c (ctf_link_deduplicating_per_cu): Likewise.
	(ctf_link_deduplicating): Likewise.
 2024-07-31 21:02:04 +01:00
Nick Alcock
2fa4b6e6df libctf, include: new functions for looking up enumerators 
Three new functions for looking up the enum type containing a given
enumeration constant, and optionally that constant's value.

The simplest, ctf_lookup_enumerator, looks up a root-visible enumerator by
name in one dict: if the dict contains multiple such constants (which is
possible for dicts created by older versions of the libctf deduplicator),
ECTF_DUPLICATE is returned.

The next simplest, ctf_lookup_enumerator_next, is an iterator which returns
all enumerators with a given name in a given dict, whether root-visible or
not.

The most elaborate, ctf_arc_lookup_enumerator_next, finds all
enumerators with a given name across all dicts in an entire CTF archive,
whether root-visible or not, starting looking in the shared parent dict;
opened dicts are cached (as with all other ctf_arc_*lookup functions) so
that repeated use does not incur repeated opening costs.

All three of these return enumerator values as int64_t: unfortunately, API
compatibility concerns prevent us from doing the same with the other older
enum-related functions, which all return enumerator constant values as ints.
We may be forced to add symbol-versioning compatibility aliases that fix the
other functions in due course, bumping the soname for platforms that do not
support such things.

ctf_arc_lookup_enumerator_next is implemented as a nested ctf_archive_next
iterator, and inside that, a nested ctf_lookup_enumerator_next iterator
within each dict.  To aid in this, add support to ctf_next_t iterators for
iterators that are implemented in terms of two simultaneous nested iterators
at once.  (It has always been possible for callers to use as many nested or
semi-overlapping ctf_next_t iterators as they need, which is one of the
advantages of this style over the _iter style that calls a function for each
thing iterated over: the iterator change here permits *ctf_next_t iterators
themselves* to be implemented by iterating using multiple other iterators as
part of their internal operation, transparently to the caller.)

Also add a testcase that tests all these functions (which is fairly easy
because ctf_arc_lookup_enumerator_next is implemented in terms of
ctf_lookup_enumerator_next) in addition to enumeration addition in
ctf_open()ed dicts, ctf_add_enumerator duplicate enumerator addition, and
conflicting enumerator constant deduplication.

include/
	* ctf-api.h (ctf_lookup_enumerator): New.
	(ctf_lookup_enumerator_next): Likewise.
	(ctf_arc_lookup_enumerator_next): Likewise.

libctf/
	* libctf.ver: Add them.
	* ctf-impl.h (ctf_next_t) <ctn_next_inner>: New.
	* ctf-util.c (ctf_next_copy): Copy it.
        (ctf_next_destroy): Destroy it.
	* ctf-lookup.c (ctf_lookup_enumerator): New.
	(ctf_lookup_enumerator_next): New.
	* ctf-archive.c (ctf_arc_lookup_enumerator_next): New.
	* testsuite/libctf-lookup/enumerator-iteration.*: New test.
	* testsuite/libctf-lookup/enum-ctf-2.c: New test CTF, used by the
	  above.
 2024-06-18 13:20:32 +01:00
Nick Alcock
4bbc4b1f5c libctf: make the ctf_next ctn_fp non-const 
This was always an error, because the ctn_fp routinely has errors set on it,
which is not something you can (or should) do to a const object.

libctf/
	* ctf-impl.h (ctf_next_) <cu.ctn_fp>: Make non-const.
 2024-06-18 13:20:32 +01:00
Nick Alcock
6e09d4a6e6 libctf: prohibit addition of enums with overlapping enumerator constants 
libctf has long prohibited addition of enums with overlapping constants in a
single enum, but now that we are properly considering enums with overlapping
constants to be conflciting types, we can go further and prohibit addition
of enumeration constants to a dict if they already exist in any enum in that
dict: the same rules as C itself.

We do this in a fashion vaguely similar to what we just did in the
deduplicator, by considering enumeration constants as identifiers and adding
them to the core type/identifier namespace, ctf_dict_t.ctf_names.  This is a
little fiddly, because we do not want to prohibit opening of existing dicts
into which the deduplicator has stuffed enums with overlapping constants!
We just want to prohibit the addition of *new* enumerators that violate that
rule.  Even then, it's fine to add overlapping enumerator constants as long
as at least one of them is in a non-root type.  (This is essential for
proper deduplicator operation in cu-mapped mode, where multiple compilation
units can be smashed into one dict, with conflicting types marked as
hidden: these types may well contain overlapping enumerators.)

So, at open time, keep track of all enums observed, then do a third pass
through the enums alone, adding each enumerator either to the ctf_names
table as a mapping from the enumerator name to the enum it is part of (if
not already present), or to a new ctf_conflicting_enums hashtable that
tracks observed duplicates. (The latter is not used yet, but will be soon.)

(We need to do a third pass because it's quite possible to have an enum
containing an enumerator FOO followed by a type FOO: since they're processed
in order, the enumerator would be processed before the type, and at that
stage it seems nonconflicting.  The easiest fix is to run through the
enumerators after all type names are interned.)

At ctf_add_enumerator time, if the enumerator to which we are adding a type
is root-visible, check for an already-present name and error out if found,
then intern the new name in the ctf_names table as is done at open time.

(We retain the existing code which scans the enum itself for duplicates
because it is still an error to add an enumerator twice to a
non-root-visible enum type; but we only need to do this if the enum is
non-root-visible, so the cost of enum addition is reduced.)

Tested in an upcoming commit.

libctf/
	* ctf-impl.h (ctf_dict_t) <ctf_names>: Augment comment.
        <ctf_conflicting_enums>: New.
	(ctf_dynset_elements): New.
	* ctf-hash.c (ctf_dynset_elements): Implement it.
	* ctf-open.c (init_static_types): Split body into...
        (init_static_types_internal): ... here.  Count enumerators;
        keep track of observed enums in pass 2; populate ctf_names and
        ctf_conflicting_enums with enumerators in a third pass.
	(ctf_dict_close): Free ctf_conflicting_enums.
	* ctf-create.c (ctf_add_enumerator): Prohibit addition of duplicate
        enumerators in root-visible enum types.

include/
	* ctf-api.h (CTF_ADD_NONROOT): Describe what non-rootness
        means for enumeration constants.
	(ctf_add_enumerator):  The name is not a misnomer.
        We now require that enumerators have unique names.
        Document the non-rootness of enumerators.
 2024-06-18 13:20:32 +01:00
Nick Alcock
f8da1a05db libctf: dedup: enums with overlapping enumerators are conflicting 
The CTF deduplicator was not considering enumerators inside enum types to be
things that caused type conflicts, so if the following two TUs were linked
together, you would end up with the following in the resulting dict:

1.c:
enum foo { A, B };

2.c:
enum bar { A, B };

linked:

enum foo { A, B };
enum bar { A, B };

This does work -- but it's not something that's valid C, and the general
point of the shared dict is that it is something that you could potentially
get from any valid C TU.

So consider such types to be conflicting, but obviously don't consider
actually identical enums to be conflicting, even though they too have (all)
their identifiers in common.  This involves surprisingly little code. The
deduplicator detects conflicting types by counting types in a hash table of
hash tables:

decorated identifier -> (type hash -> count)

where the COUNT is the number of times a given hash has been observed: any
name with more than one hash associated with it is considered conflicting
(the count is used to identify the most common such name for promotion to
the shared dict).

Before now, those identifiers were all the identifiers of types (possibly
decorated with their namespace on the front for enumerator identifiers), but
we can equally well put *enumeration constant names* in there, undecorated
like the identifiers of types in the global namespace, with the type hash
being the hash of each enum containing that enumerator.  The existing
conflicting-type-detection code will then accurately identify distinct enums
with enumeration constants in common.  The enum that contains the most
commonly-appearing enumerators will be promoted to the shared dict.

libctf/
	* ctf-impl.h (ctf_dedup_t) <cd_name_counts>: Extend comment.
	* ctf-dedup.c (ctf_dedup_count_name): New, split out of...
	(ctf_dedup_populate_mappings): ... here.  Call it for all
	* enumeration constants in an enum as well as types.

ld/
	* testsuite/ld-ctf/enum-3.c: New test CTF.
	* testsuite/ld-ctf/enum-4.c: Likewise.
	* testsuite/ld-ctf/overlapping-enums.d: New test.
	* testsuite/ld-ctf/overlapping-enums-2.d: Likewise.
 2024-06-18 13:20:31 +01:00
Nick Alcock
483546ce4f libctf: make ctf_serialize() actually serialize 
ctf_serialize() evolved from the old ctf_update(), which mutated the
in-memory CTF dict to make all the dynamic in-memory types into static,
unchanging written-to-the-dict types (by deserializing and reserializing
it): back in the days when you could only do type lookups on static types,
this meant you could see all the types you added recently, at the small,
small cost of making it impossible to change those older types ever again
and inducing an amortized O(n^2) cost if you actually wanted to add
references to types you added at arbitrary times to later types.

It also reset things so that ctf_discard() would throw away only types you
added after the most recent ctf_update() call.

Some time ago this was all changed so that you could look up dynamic types
just as easily as static types: ctf_update() changed so that only its
visible side-effect of affecting ctf_discard() remained: the old
ctf_update() was renamed to ctf_serialize(), made internal to libctf, and
called from the various functions that wrote files out.

... but it was still working by serializing and deserializing the entire
dict, swapping out its guts with the newly-serialized copy in an invasive
and horrible fashion that coupled ctf_serialize() to almost every field in
the ctf_dict_t.  This is totally useless, and fixing it is easy: just rip
all that code out and have ctf_serialize return a serialized representation,
and let everything use that directly.  This simplifies most of its callers
significantly.

(It also points up another bug: ctf_gzwrite() failed to call ctf_serialize()
at all, so it would only ever work for a dict you just ctf_write_mem()ed
yourself, just for its invisible side-effect of serializing the dict!)

This lets us simplify away a bunch of internal-only open-side functionality
for overriding the syn_ext_strtab and some just-added functionality for
forcing in an existing atoms table, without loss of functionality, and lets
us lift the restriction on reserializing a dict that was ctf_open()ed rather
than being ctf_create()d: it's now perfectly OK to open a dict, modify it
(except for adding members to existing structs, unions, or enums, which
fails with -ECTF_RDONLY), and write it out again, just as one would expect.

libctf/

	* ctf-serialize.c (ctf_symtypetab_sect_sizes): Fix typos.
	(ctf_type_sect_size): Add static type sizes too.
	(ctf_serialize): Return the new dict rather than updating the
	existing dict.  No longer fail for dicts with static types;
	copy them onto the start of the new types table.
	(ctf_gzwrite): Actually serialize before gzwriting.
	(ctf_write_mem): Improve forced (test-mode) endian-flipping:
	flip dicts even if they are too small to be compressed.
	Improve confusing variable naming.
	* ctf-archive.c (arc_write_one_ctf): Don't bother to call
	ctf_serialize: both the functions we call do so.
	* ctf-string.c (ctf_str_create_atoms): Drop serializing case
	(atoms arg).
	* ctf-open.c (ctf_simple_open): Call ctf_bufopen directly.
	(ctf_simple_open_internal): Delete.
	(ctf_bufopen_internal): Delete/rename to ctf_bufopen: no
	longer bother with syn_ext_strtab or forced atoms table,
	serialization no longer needs them.
	* ctf-create.c (ctf_create): Call ctf_bufopen directly.
	* ctf-impl.h (ctf_str_create_atoms): Drop atoms arg.
	(ctf_simple_open_internal): Delete.
	(ctf_bufopen_internal): Likewise.
	(ctf_serialize): Adjust.
	* testsuite/libctf-lookup/add-to-opened.c: Adjust now that
	this is supposed to work.
 2024-04-19 16:14:47 +01:00
Nick Alcock
cf9da3b0b6 libctf: rethink strtab writeout 
This commit finally adjusts strtab writeout so that repeated writeouts, or
writeouts of a dict that was read in earlier, only sorts the portion of the
strtab that was newly added.

There are three intertwined changes here:

 - pull the contents of strtabs from newly ctf_bufopened dicts into the
   atoms table, so that future additions will reuse the existing offset etc
   rather than adding new identical strings
 - allow the internal ctf_bufopen done by serialization to contribute its
   existing atoms table, so that existing atoms can be used for the
   remainder of the open process (like name table construction): this atoms
   table currente gets thrown away in the mass reassignment done later in
   ctf_serialize in any case, but it needs to be there during the open.
 - rewrite ctf_str_write_strtab so that a) it uses iterators rather than
   ctf_*_iter, reducing pointless structures which serve no other purpose
   than to implement ordinary variable scope, but more clunkily, and b)
   retains the existing strtab on the front of the new one, with its sort
   retained, rather than resorting, so all existing already-written strtab
   offsets remain valid across the call.

This latter change finally permits repeated serializations, and
reserializations of ctf_open()ed dicts, to work, but for now we keep the
code that prevents that because serialization is about to change again in a
way that will make it more obvious that doing such things is safe, and we
can take it out then.

(There are also some smaller changes like moving the purge of the refs table
into ctf_str_write_strtab(), since that's where the changes happen that
invalidate it, rather than doing it in ctf_serialize().  We also prohibit
something that has never worked, opening a dict and then reporting symbols
to it via ctf_link_add_strtab() et al: you must do that to newly-created
dicts which have had stuff ctf_link()ed into them.  This is very unlikely
ever to be a problem in practice: linkers just don't do that sort of thing.)

libctf/

	* ctf-create.c (ctf_create): Add (temporary) atoms arg.
	* ctf-impl.h (struct ctf_dict.ctf_dynstrtab): New.
	(ctf_str_create_atoms): Adjust.
	(ctf_str_write_strtab): Likewise.
	(ctf_simple_open_internal): Likewise.
	* ctf-open.c (ctf_simple_open_internal): Add atoms arg.
	(ctf_bufopen): Likewise.
	(ctf_bufopen_internal): Initialize just enough of an
	atoms table: pre-init from the atoms arg if supplied.
	(ctf_simple_open): Adjust.
	* ctf-serialize.c (ctf_serialize): Constify the strtab.
	Move ref list purging into ctf_str_write_strtab.
	Initialize the new dict with the old dict's atoms table.
	Accept the new strtab from ctf_str_write_strtab.
	Adjust for addition of ctf_dynstrtab.
	* ctf-string.c (ctf_strraw_explicit): Improve comments.
	(ctf_str_create_atoms): Prepopulate from an existing atoms table,
	or alternatively pull in all strings from the strtab and turn
	them into atoms.
	(ctf_str_free_atoms): Free the dynstrtab and its strtab.
	(struct ctf_strtab_write_state): Remove.
	(ctf_str_count_strtab): Fold this...
	(ctf_str_populate_sorttab): ... and this...
	(ctf_str_write_strtab): ... into this.  Prepend existing strings
	to the strtab rather than resorting them (and wrecking their
	offsets).  Keep the dynstrtab updated.  Update refs for all
	atoms with refs, whether or not they are strings newly added
	to the strtab.
 2024-04-19 16:14:47 +01:00
Nick Alcock
149ce5c263 libctf: replace 'pending refs' abstraction 
A few years ago we introduced a 'pending refs' abstraction to fix one
problem: serializing a dict, then changing it would tend to corrupt the dict
because the strtab sort we do on strtab writeout (to improve compression
efficiency) would modify the offset of any strings that sorted
lexicographically earlier in the strtab: so we added a new restriction that
all strings are added only at serialization time, and maintained a set of
'pending' refs that were added earlier, whose offsets we could update (like
other refs) at writeout time.

This was in hindsight seriously problematic for maintenance (because
serialization has to traverse all strings in all datatypes in the entire
dict), and has become impossible to sustain now that we can read in existing
dicts, modify them, and reserialize them again.  We really don't want to
have to dig through the entire dict we jut read in just in order to dig out
all its strtab offsets, then *change* it, just for the sake of a sort that
adds a frankly trivial amount of compression efficiency.

Sorting *is* still worthwhile -- but it sacrifices very little to only sort
newly-added portions of the strtab, reusing older portions as necessary.
As a first stage in this, discard the whole "pending refs" abstraction and
replace it with "movable" refs, which are exactly like all other refs
(addresses containing the strtab offset of some string, which are updated
wiht the final strtab offset on serialization) except that we track them in
a reverse dict so that we can move the refs around (which we do whenever we
realloc() a buffer containing a bunch of structure members or something when
we add members to the structure).

libctf/

	* ctf-create.c (ctf_add_enumerator): Call ctf_str_move_refs; add
        a movable ref.
	(ctf_add_member_offset): Likewise.
	* ctf-util.c (ctf_realloc): Delete.
	* ctf-serialize.c (ctf_serialize): No longer use it.  Adjust to
	new fields.
	* ctf-string.c (ctf_str_purge_atom_refs): Purge movable refs.
	(ctf_str_free_atom): Free freeable atoms' strings.
	(ctf_str_create_atoms): Create the movable refs dynhash if needed.
	(ctf_str_free_atoms): Destroy it.
	(CTF_STR_MOVABLE): Switch (back) from ints to flags (see previous
	reversion).  Add new flag.
	(aref_create):  New, populate movable refs if need be.
	(ctf_str_add_ref_internal): Switch back to flags, update refs
	directly for nonprovisional strings (with already-known fixed offsets);
	create refs via aref_create.  Allocate strings only if not within an
	mmapped strtab.
	(ctf_str_add_movable_ref): New.
	(ctf_str_add): Adjust to CTF_STR_* reintroduction.
	(ctf_str_add_external): LIkewise.
	(ctf_str_move_refs): New, move refs via ctf_str_movable_refs
	backpointer.
	(ctf_str_purge_refs): Drop ctf_str_num_refs.
	(ctf_str_update_refs): Fix indentation.
	* ctf-impl.h (struct ctf_str_atom_movable): New.
	(struct ctf_dict.ctf_str_num_refs): Drop.
	(struct ctf_dict.ctf_str_movable_refs): New.
	(ctf_str_add_movable_ref): Declare.
	(ctf_str_move_refs): Likewise.
	(ctf_realloc): Drop.
 2024-04-19 16:14:46 +01:00
Nick Alcock
3301ddba1b Revert "libctf: do not corrupt strings across ctf_serialize" 
This reverts commit 986e9e3aa0.

(We do not revert the testcase -- it remains valid -- but we are
taking a different, less complex and more robust approach.)

This also deletes the pending refs abstraction without (yet)
replacing it, so some tests will fail for a commit or two.
 2024-04-19 16:14:46 +01:00
Nick Alcock
629acbe4a3 libctf: rename ctf_dict.ctf_{symtab,strtab} 
These two fields are constantly confusing because CTF dicts contain both
a symtypetab and strtab, but these fields are not that: they are the
symtab and strtab from the ELF file.  We have enough string tables now
(internal, external, synthetic external, dynamic) that we need to at
least name them better than this to avoid getting totally confused.
Rename them to ctf_ext_symtab and ctf_ext_strtab.

libctf/

	* ctf-dump.c (ctf_dump_objts): Rename ctf_symtab -> ctf_ext_symtab.
	* ctf-impl.h (struct ctf_dict.ctf_symtab): Rename to...
	(struct ctf_dict.ctf_ext_strtab): ... this.
	(struct ctf_dict.ctf_strtab): Rename to...
	(struct ctf_dict.ctf_ext_strtab): ... this.
	* ctf-lookup.c (ctf_lookup_symbol_name): Adapt.
	(ctf_lookup_symbol_idx): Adapt.
	(ctf_lookup_by_sym_or_name): Adapt.
	* ctf-open.c (ctf_bufopen_internal): Adapt.
	(ctf_dict_close): Adapt.
	(ctf_getsymsect): Adapt.
	(ctf_getstrsect): Adapt.
	(ctf_symsect_endianness): Adapt.
 2024-04-19 16:14:46 +01:00
Nick Alcock
bb2a9a465e libctf: fix a comment typo 
ctf_update has been called ctf_serialize for years now.

libctf/

	* ctf-impl.h: Fix comment typo.
 2024-04-19 16:14:46 +01:00
Nick Alcock
4fa4e3d92a libctf: delete LCTF_DIRTY 
This flag was meant as an optimization to avoid reserializing dicts
unnecessarily.  It was critically necessary back when serialization was
done by ctf_update() and you had to call that every time you wanted any
new modifications to the type table to be usable by other types, but
that has been unnecessary for years now, and serialization is only done
once when writing out, which one would naturally assume would always
serialize the dict.  Worse, it never really worked: it only tracked
newly-added types, not things like added symbols which might equally
well require reserialization, and it gets in the way of an upcoming
change.  Delete entirely.

libctf/

	* ctf-create.c (ctf_create): Drop LCTF_DIRTY.
	(ctf_discard): Likewise.
	(ctf_rollback): Likewise.
	(ctf_add_generic): Likewise.
	(ctf_set_array): Likewise.
	(ctf_add_enumerator): Likewise.
	(ctf_add_member_offset): Likewise.
	(ctf_add_variable_forced): Likewise.
	* ctf-link.c (ctf_link_intern_extern_string): Likewise.
	(ctf_link_add_strtab): Likewise.
	* ctf-serialize.c (ctf_serialize): Likewise.
	* ctf-impl.h (LCTF_DIRTY): Likewise.
	(LCTF_LINKING): Renumber.
 2024-04-19 16:14:46 +01:00
Nick Alcock
8a60c93096 libctf: support addition of types to dicts read via ctf_open() 
libctf has long declared deserialized dictionaries (out of files or ELF
sections or memory buffers or whatever) to be read-only: back in the
furthest prehistory this was not the case, in that you could add a
few sorts of type to such dicts, but attempting to do so often caused
horrible memory corruption, so I banned the lot.

But it turns out real consumers want it (notably DTrace, which
synthesises pointers to types that don't have them and adds them to the
ctf_open()ed dicts if it needs them). Let's bring it back again, but
without the memory corruption and without the massive code duplication
required in days of yore to distinguish between static and dynamic
types: the representation of both types has been identical for a few
years, with the only difference being that types as a whole are stored in
a big buffer for types read in via ctf_open and per-type hashtables for
newly-added types.

So we discard the internally-visible concept of "readonly dictionaries"
in favour of declaring the *range of types* that were already present
when the dict was read in to be read-only: you can't modify them (say,
by adding members to them if they're structs, or calling ctf_set_array
on them), but you can add more types and point to them.  (The API
remains the same, with calls sometimes returning ECTF_RDONLY, but now
they do so less often.)

This is a fairly invasive change, mostly because code written since the
ban was introduced didn't take the possibility of a static/dynamic split
into account.  Some of these irregularities were hard to define as
anything but bugs.

Notably:

 - The symbol handling was assuming that symbols only needed to be
   looked for in dynamic hashtabs or static linker-laid-out indexed/
   nonindexed layouts, but now we want to check both in case people
   added more symbols to a dict they opened.

 - The code that handles type additions wasn't checking to see if types
   with the same name existed *at all* (so you could do
   ctf_add_typedef (fp, "foo", bar) repeatedly without error).  This
   seems reasonable for types you just added, but we probably *do* want
   to ban addition of types with names that override names we already
   used in the ctf_open()ed portion, since that would probably corrupt
   existing type relationships.  (Doing things this way also avoids
   causing new errors for any existing code that was doing this sort of
   thing.)

 - ctf_lookup_variable entirely failed to work for variables just added
   by ctf_add_variable: you had to write the dict out and read it back
   in again before they appeared.

 - The symbol handling remembered what symbols you looked up but didn't
   remember their types, so you could look up an object symbol and then
   find it popping up when you asked for function symbols, which seems
   less than ideal.  Since we had to rejig things enough to be able to
   distinguish function and object symbols internally anyway (in order
   to give suitable errors if you try to add a symbol with a name that
   already existed in the ctf_open()ed dict), this bug suddenly became
   more visible and was easily fixed.

We do not (yet) support writing out dicts that have been previously read
in via ctf_open() or other deserializer (you can look things up in them,
but not write them out a second time).  This never worked, so there is
no incompatibility; if it is needed at a later date, the serializer is a
little bit closer to having it work now (the only table we don't deal
with is the types table, and that's because the upcoming CTFv4 changes
are likely to make major changes to the way that table is represented
internally, so adding more code that depends on its current form seems
like a bad idea).

There is a new testcase that tests much of this, in particular that
modification of existing types is still banned and that you can add new
ones and chase them without error.

libctf/

	* ctf-impl.h (struct ctf_dict.ctf_symhash): Split into...
	(ctf_dict.ctf_symhash_func): ... this and...
	(ctf_dict.ctf_symhash_objt): ... this.
	(ctf_dict.ctf_stypes): New, counts static types.
	(LCTF_INDEX_TO_TYPEPTR): Use it instead of CTF_RDWR.
	(LCTF_RDWR): Deleted.
	(LCTF_DIRTY): Renumbered.
	(LCTF_LINKING): Likewise.
	(ctf_lookup_variable_here): New.
	(ctf_lookup_by_sym_or_name): Likewise.
	(ctf_symbol_next_static): Likewise.
	(ctf_add_variable_forced): Likewise.
	(ctf_add_funcobjt_sym_forced): Likewise.
	(ctf_simple_open_internal): Adjust.
	(ctf_bufopen_internal): Likewise.
	* ctf-create.c (ctf_grow_ptrtab): Adjust a lot to start with.
	(ctf_create): Migrate a bunch of initializations into bufopen.
	Force recreation of name tables.  Do not forcibly override the
	model, let ctf_bufopen do it.
	(ctf_static_type): New.
	(ctf_update): Drop LCTF_RDWR check.
	(ctf_dynamic_type): Likewise.
	(ctf_add_function): Likewise.
	(ctf_add_type_internal): Likewise.
	(ctf_rollback): Check ctf_stypes, not LCTF_RDWR.
	(ctf_set_array): Likewise.
	(ctf_add_struct_sized): Likewise.
	(ctf_add_union_sized): Likewise.
	(ctf_add_enum): Likewise.
	(ctf_add_enumerator): Likewise (only on the target dict).
	(ctf_add_member_offset): Likewise.
	(ctf_add_generic): Drop LCTF_RDWR check.  Ban addition of types
	with colliding names.
	(ctf_add_forward): Note safety under the new rules.
	(ctf_add_variable): Split all but the existence check into...
	(ctf_add_variable_forced): ... this new function.
	(ctf_add_funcobjt_sym): Likewise...
	(ctf_add_funcobjt_sym_forced): ... for this new function.
	* ctf-link.c (ctf_link_add_linker_symbol): Ban calling on dicts
	with any stypes.
	(ctf_link_add_strtab): Likewise.
	(ctf_link_shuffle_syms): Likewise.
	(ctf_link_intern_extern_string): Note pre-existing prohibition.
	* ctf-lookup.c (ctf_lookup_by_id): Drop LCTF_RDWR check.
	(ctf_lookup_variable): Split out looking in a dict but not
	its parent into...
	(ctf_lookup_variable_here): ... this new function.
	(ctf_lookup_symbol_idx): Track whether looking up a function or
	object: cache them separately.
	(ctf_symbol_next): Split out looking in non-dynamic symtypetab
	entries to...
	(ctf_symbol_next_static): ... this new function.  Don't get confused
	by the simultaneous presence of static and dynamic symtypetab entries.
	(ctf_try_lookup_indexed):  Don't waste time looking up symbols by
	index before there can be any idea how symbols are numbered.
	(ctf_lookup_by_sym_or_name): Distinguish between function and
	data object lookups.  Drop LCTF_RDWR.
	(ctf_lookup_by_symbol): Adjust.
	(ctf_lookup_by_symbol_name): Likewise.
	* ctf-open.c (init_types): Rename to...
	(init_static_types): ... this.  Drop LCTF_RDWR.  Populate ctf_stypes.
	(ctf_simple_open): Drop writable arg.
	(ctf_simple_open_internal): Likewise.
	(ctf_bufopen): Likewise.
	(ctf_bufopen_internal): Populate fields only used for writable dicts.
	Drop LCTF_RDWR.
	(ctf_dict_close): Cater for symhash cache split.
	* ctf-serialize.c (ctf_serialize): Use ctf_stypes, not LCTF_RDWR.
	* ctf-types.c (ctf_variable_next): Drop LCTF_RDWR.
	* testsuite/libctf-lookup/add-to-opened*: New test.
 2024-04-19 16:14:46 +01:00
Nick Alcock
54a0219150 libctf: remove static/dynamic name lookup distinction 
libctf internally maintains a set of hash tables for type name lookups,
one for each valid C type namespace (struct, union, enum, and everything
else).

Or, rather, it maintains *two* sets of hash tables: one, a ctf_hash *,
is meant for lookups in ctf_(buf)open()ed dicts with fixed content; the
other, a ctf_dynhash *, is meant for lookups in ctf_create()d dicts.

This distinction was somewhat valuable in the far pre-binutils past when
two different hashtable implementations were used (one expanding, the
other fixed-size), but those days are long gone: the hash table
implementations are almost identical, both wrappers around the libiberty
hashtab. The ctf_dynhash has many more capabilities than the ctf_hash
(iteration, deletion, etc etc) and has no downsides other than starting
at a fixed, arbitrary small size.

That limitation is easy to lift (via a new ctf_dynhash_create_sized()),
following which we can throw away nearly all the ctf_hash
implementation, and all the code to choose between readable and writable
hashtabs; the few convenience functions that are still useful (for
insertion of name -> type mappings) can also be generalized a bit so
that the extra string verification they do is potentially available to
other string lookups as well.

(libctf still has two hashtable implementations, ctf_dynhash, above,
and ctf_dynset, which is a key-only hashtab that can avoid a great many
malloc()s, used for high-volume applications in the deduplicator.)

libctf/

	* ctf-create.c (ctf_create): Eliminate ctn_writable.
	(ctf_dtd_insert): Likewise.
	(ctf_dtd_delete): Likewise.
	(ctf_rollback): Likewise.
	(ctf_name_table): Eliminate ctf_names_t.
	* ctf-hash.c (ctf_dynhash_create): Comment update.
        Reimplement in terms of...
	(ctf_dynhash_create_sized): ... this new function.
	(ctf_hash_create): Remove.
	(ctf_hash_size): Remove.
	(ctf_hash_define_type): Remove.
	(ctf_hash_destroy): Remove.
	(ctf_hash_lookup_type): Rename to...
	(ctf_dynhash_lookup_type): ... this.
	(ctf_hash_insert_type): Rename to...
	(ctf_dynhash_insert_type): ... this, moving validation to...
	* ctf-string.c (ctf_strptr_validate): ... this new function.
	* ctf-impl.h (struct ctf_names): Extirpate.
	(struct ctf_lookup.ctl_hash): Now a ctf_dynhash_t.
	(struct ctf_dict): All ctf_names_t fields are now ctf_dynhash_t.
	(ctf_name_table): Now returns a ctf_dynhash_t.
	(ctf_lookup_by_rawhash): Remove.
	(ctf_hash_create): Likewise.
	(ctf_hash_insert_type): Likewise.
	(ctf_hash_define_type): Likewise.
	(ctf_hash_lookup_type): Likewise.
	(ctf_hash_size): Likewise.
	(ctf_hash_destroy): Likewise.
	(ctf_dynhash_create_sized): New.
	(ctf_dynhash_insert_type): New.
	(ctf_dynhash_lookup_type): New.
	(ctf_strptr_validate): New.
	* ctf-lookup.c (ctf_lookup_by_name_internal): Adapt.
	* ctf-open.c (init_types): Adapt.
	(ctf_set_ctl_hashes): Adapt.
	(ctf_dict_close): Adapt.
	* ctf-serialize.c (ctf_serialize): Adapt.
	* ctf-types.c (ctf_lookup_by_rawhash): Remove.
 2024-04-19 16:14:46 +01:00
Alan Modra
fd67aa1129 Update year range in copyright notice of binutils files 
Adds two new external authors to etc/update-copyright.py to cover
bfd/ax_tls.m4, and adds gprofng to dirs handled automatically, then
updates copyright messages as follows:

1) Update cgen/utils.scm emitted copyrights.
2) Run "etc/update-copyright.py --this-year" with an extra external
   author I haven't committed, 'Kalray SA.', to cover gas testsuite
   files (which should have their copyright message removed).
3) Build with --enable-maintainer-mode --enable-cgen-maint=yes.
4) Check out */po/*.pot which we don't update frequently.
 2024-01-04 22:58:12 +10:30
Torbjörn SVENSSON
998a4f589d libctf: Sanitize error types for PR 30836 
Made sure there is no implicit conversion between signed and unsigned
return value for functions setting the ctf_errno value.
An example of the problem is that in ctf_member_next, the "offset" value
is either 0L or (ctf_id_t)-1L, but it should have been 0L or -1L.
The issue was discovered while building a 64 bit ld binary to be
executed on the Windows platform.
Example object file that demonstrates the issue is attached in the PR.

libctf/
	Affected functions adjusted.

Signed-off-by: Torbjörn SVENSSON <torbjorn.svensson@foss.st.com>
Co-Authored-By: Yvan ROUX <yvan.roux@foss.st.com>
 2023-10-17 17:31:20 +02:00
Alan Modra
d87bef3a7b Update year range in copyright notice of binutils files 
The newer update-copyright.py fixes file encoding too, removing cr/lf
on binutils/bfdtest2.c and ld/testsuite/ld-cygwin/exe-export.exp, and
embedded cr in binutils/testsuite/binutils-all/ar.exp string match.
 2023-01-01 21:50:11 +10:30
Nick Alcock
6bd2318f32 libctf: fix linking together multiple objects derived from the same source 
Right now, if you compile the same .c input repeatedly with CTF enabled
and different compilation flags, then arrange to link all of these
together, then things misbehave in various ways.  libctf may conflate
either inputs (if the .o files have the same name, say if they are
stored in different .a archives), or per-CU outputs when conflicting
types are found: the latter can lead to entirely spurious errors when
it tries to produce multiple per-CU outputs with the same name
(discarding all but the last, but then looking for types in the earlier
ones which have just been thrown away).

Fixing this is multi-pronged.  Both inputs and outputs need to be
differentiated in the hashtables libctf keeps them in: inputs with the
same cuname and filename need to be considered distinct as long as they
have different associated CTF dicts, and per-CU outputs need to be
considered distinct as long as they have different associated input
dicts.  Right now there is nothing tying the two together other than the
CU name: fix this by introducing a new field in the ctf_dict_t named
ctf_link_in_out, which (for input dicts) points to the associated per-CU
output dict (if any), and for output dicts points to the associated
input dict.  At creation time the name used is completely arbitrary:
it's only important that it be distinct if CTF dicts are distinct.  So,
when a clash is found, adjust the CU name by sticking the number of
elements in the input on the end.  At output time, the CU name will
appear in the linked object, so it matters a little more that it look
slightly less ugly: in conflicting cases, append an incrementing
integer, starting at 0.

This naming scheme is not very helpful, but it's hard to see what else
we can do.  The input .o name may be the same.  The input .a name is not
even visible to ctf_link, and even *that* might be the same, because
.a's can contain many members with the same name, all of which
participate in the link.  All we really know is that the two have
distinct dictionaries with distinct types in them, and at least this way
they are all represented, any any symbols, variables etc referring to
those types are accurately stored.

(As a side-effect this also fixes a use-after-free and double-free when
errors are found during variable or symbol emission.)

Use the opportunity to prevent a couple of sources of problems, to wit
changing the active CU mappings when a link has already been done
(no effect on ld, which doesn't use CU mappings at all), and causing
multiple consecutive ctf_link's to have the same net effect as just
doing the last one (no effect on ld, which only ever does one
ctf_link) rather than having the links be a sort of half-incremental
not-really-intended mess.

libctf/ChangeLog:

	PR libctf/29242
	* ctf-impl.h (struct ctf_dict) [ctf_link_in_out]: New.
	* ctf-dedup.c (ctf_dedup_emit_type): Set it.
	* ctf-link.c (ctf_link_add_ctf_internal): Set the input
	CU name uniquely when clashes are found.
	(ctf_link_add): Document what repeated additions do.
	(ctf_new_per_cu_name): New, come up with a consistent
	name for a new per-CU dict.
	(ctf_link_deduplicating): Use it.
	(ctf_create_per_cu): Use it, and ctf_link_in_out, and set
	ctf_link_in_out properly.  Don't overwrite per-CU dicts with
	per-CU dicts relating to different inputs.
	(ctf_link_add_cu_mapping): Prevent per-CU mappings being set up
	if we already have per-CU outputs.
	(ctf_link_one_variable): Adjust ctf_link_per_cu call.
	(ctf_link_deduplicating_one_symtypetab): Likewise.
	(ctf_link_empty_outputs): New, delete all the ctf_link_outputs
	and blank out ctf_link_in_out on the corresponding inputs.
	(ctf_link): Clarify the effect of multiple ctf_link calls.
	Empty ctf_link_outputs if it already exists rather than
	having the old output leak into the new link.  Fix a variable
	name.
	* testsuite/config/default.exp (AR): Add.
	(OBJDUMP): Likewise.
	* testsuite/libctf-regression/libctf-repeat-cu.exp: New test.
	* testsuite/libctf-regression/libctf-repeat-cu*: Main program,
	library, and expected results for the test.
 2022-06-21 19:27:15 +01:00
Nick Alcock
faf5e6ace8 libctf: add LIBCTF_WRITE_FOREIGN_ENDIAN debugging option 
libctf has always handled endianness differences by detecting
foreign-endian CTF dicts on the input and endian-flipping them: dicts
are always written in native endianness.  This makes endian-awareness
very low overhead, but it means that the foreign-endian code paths
almost never get routinely tested, since "make check" usually reads in
dicts ld has just written out: only a few corrupted-CTF tests are
actually in fixed endianness, and even they only test the foreign-
endian code paths when you run make check on a big-endian machine.
(And the fix is surely not to add more .s-based tests like that, because
they are a nightmare to maintain compared to the C-code-based ones.)

To improve on this, add a new environment variable,
LIBCTF_WRITE_FOREIGN_ENDIAN, which causes libctf to unconditionally
endian-flip at ctf_write time, so the output is always in the wrong
endianness.  This then tests the foreign-endian read paths properly
at open time.

Make this easier by restructuring the writeout code in ctf-serialize.c,
which duplicates the maybe-gzip-and-write-out code three times (once
for ctf_write_mem, with thresholding, and once each for
ctf_compress_write and ctf_write just so those can avoid thresholding
and/or compression).  Instead, have the latter two call the former
with thresholds of 0 or (size_t) -1, respectively.

The endian-flipping code itself gains a bit of complexity, because
one single endian-flipper (flip_types) was assuming the input to be
in foreign-endian form and assuming it could pull things out of the
input once they had been flipped and make sense of them. At the
cost of a few lines of duplicated initializations, teach it to
read before flipping if we're flipping to foreign-endianness instead
of away from it.

libctf/
	* ctf-impl.h (ctf_flip_header): No longer static.
	(ctf_flip): Likewise.
	* ctf-open.c (flip_header): Rename to...
	(ctf_flip_header): ... this, now it is not private to one file.
	(flip_ctf): Rename...
	(ctf_flip): ... this too.  Add FOREIGN_ENDIAN arg.
	(flip_types): Likewise.  Use it.
	(ctf_bufopen_internal): Adjust calls.
	* ctf-serialize.c (ctf_write_mem): Add flip_endian path via
	a newly-allocated bounce buffer.
	(ctf_compress_write): Move below ctf_write_mem and reimplement
	in terms of it.
	(ctf_write): Likewise.
	(ctf_gzwrite): Note that this obscure writeout function does not
	support endian-flipping.
 2022-03-23 13:48:32 +00:00
Alan Modra
a2c5833233 Update year range in copyright notice of binutils files 
The result of running etc/update-copyright.py --this-year, fixing all
the files whose mode is changed by the script, plus a build with
--enable-maintainer-mode --enable-cgen-maint=yes, then checking
out */po/*.pot which we don't update frequently.

The copy of cgen was with commit d1dd5fcc38ead reverted as that commit
breaks building of bfp opcodes files.
 2022-01-02 12:04:28 +10:30
Alan Modra
4821e618ad Use htab_eq_string in libctf 
* ctf-impl.h (ctf_dynset_eq_string): Don't declare.
	* ctf-hash.c (ctf_dynset_eq_string): Delete function.
	* ctf-dedup.c (make_set_element): Use htab_eq_string.
	(ctf_dedup_atoms_init, ADD_CITER, ctf_dedup_init): Likewise.
	(ctf_dedup_conflictify_unshared): Likewise.
	(ctf_dedup_walk_output_mapping): Likewise.
 2021-05-09 12:28:32 +09:30
Alan Modra
e93388417c Provide an inline startswith function in bfd.h 
bfd/
	* bfd-in.h (startswith): New inline.
	(CONST_STRNEQ): Use startswith.
	* bfd-in2.h: Regenerate.
gdbsupport/
	* common-utils.h (startswith): Delete version now supplied by bfd.h.
libctf/
	* ctf-impl.h: Include string.h.
 2021-03-21 23:00:32 +10:30
Nick Alcock
d7b1416ef2 libctf: types: unify code dealing with small-vs-large struct members 
This completes the job of unifying what was once three separate code
paths full of duplication for every function dealing with querying the
properties of struct and union members.  The dynamic code path was
already removed: this change removes the distinction between small and
large members, by adding a helper that copies out members from the vlen,
expanding small members into large ones as it does so.

This makes it possible to have *more* representations of things like
structure members without needing to change the querying functions at
all.  It also lets us check for buffer overruns more effectively,
verifying that we don't accidentally overrun the end of the vlen in
either the dynamic or static type case.

libctf/ChangeLog
2021-03-18  Nick Alcock  <nick.alcock@oracle.com>

	* ctf-impl.h (ctf_next_t) <ctn_tp>: New.
	<u.ctn_mp>: Remove.
	<u.ctn_lmp>: Remove.
	<u.ctn_vlen>: New.
	* ctf-types.c (ctf_struct_member): New.
	(ctf_member_next): Use it, dropping separate large/small code paths.
	(ctf_type_align): Likewise.
	(ctf_member_info): Likewise.
	(ctf_type_rvisit): Likewise.
 2021-03-18 12:40:41 +00:00
Nick Alcock
08c428aff4 libctf: eliminate dtd_u, part 5: structs / unions 
Eliminate the dynamic member storage for structs and unions as we have
for other dynamic types.  This is much like the previous enum
elimination, except that structs and unions are the only types for which
a full-sized ctf_type_t might be needed.  Up to now, this decision has
been made in the individual ctf_add_{struct,union}_sized functions and
duplicated in ctf_add_member_offset.  The vlen machinery lets us
simplify this, always allocating a ctf_lmember_t and setting the
dtd_data's ctt_size to CTF_LSIZE_SENT: we figure out whether this is
really justified and (almost always) repack things down into a
ctf_stype_t at ctf_serialize time.

This allows us to eliminate the dynamic member paths from the iterators and
query functions in ctf-types.c in favour of always using the large-structure
vlen stuff for dynamic types (the diff is ugly but that's just because of the
volume of reindentation this calls for).  This also means the large-structure
vlen stuff gets more heavily tested, which is nice because it was an almost
totally unused code path before now (it only kicked in for structures of size
>4GiB, and how often do you see those?)

The only extra complexity here is ctf_add_type.  Back in the days of the
nondeduplicating linker this was called a ridiculous number of times for
countless identical copies of structures: eschewing the repeated lookups of the
dtd in ctf_add_member_offset and adding the members directly saved an amazing
amount of time.  Now the nondeduplicating linker is gone, this is extreme
overoptimization: we can rip out the direct addition and use ctf_member_next and
ctf_add_member_offset, just like ctf_dedup_emit does.

We augment a ctf_add_type test to try adding a self-referential struct, the only
thing the ctf_add_type part of this change really perturbs.

This completes the elimination of dtd_u.

libctf/ChangeLog
2021-03-18  Nick Alcock  <nick.alcock@oracle.com>

	* ctf-impl.h (ctf_dtdef_t) <dtu_members>: Remove.
	<dtd_u>: Likewise.
	(ctf_dmdef_t): Remove.
	(struct ctf_next) <u.ctn_dmd>: Remove.
	* ctf-create.c (INITIAL_VLEN): New, more-or-less arbitrary initial
	vlen size.
	(ctf_add_enum): Use it.
	(ctf_dtd_delete): Do not free the (removed) dmd; remove string
	refs from the vlen on struct deletion.
	(ctf_add_struct_sized): Populate the vlen: do it by hand if
	promoting forwards.  Always populate the full-size
	lsizehi/lsizelo members.
	(ctf_add_union_sized): Likewise.
	(ctf_add_member_offset): Set up the vlen rather than the dmd.
	Expand it as needed, repointing string refs via
	ctf_str_move_pending. Add the member names as pending strings.
	Always populate the full-size lsizehi/lsizelo members.
	(membadd): Remove, folding back into...
	(ctf_add_type_internal): ... here, adding via an ordinary
	ctf_add_struct_sized and _next iteration rather than doing
	everything by hand.
	* ctf-serialize.c (ctf_copy_smembers): Remove this...
	(ctf_copy_lmembers): ... and this...
	(ctf_emit_type_sect): ... folding into here. Figure out if a
	ctf_stype_t is needed here, not in ctf_add_*_sized.
	(ctf_type_sect_size): Figure out the ctf_stype_t stuff the same
	way here.
	* ctf-types.c (ctf_member_next): Remove the dmd path and always
	use the vlen.  Force large-structure usage for dynamic types.
	(ctf_type_align): Likewise.
	(ctf_member_info): Likewise.
	(ctf_type_rvisit): Likewise.
	* testsuite/libctf-regression/type-add-unnamed-struct-ctf.c: Add a
	self-referential type to this test.
	* testsuite/libctf-regression/type-add-unnamed-struct.c: Adjusted
	accordingly.
	* testsuite/libctf-regression/type-add-unnamed-struct.lk: Likewise.
 2021-03-18 12:40:40 +00:00