I noticed that dwarf_unit_type_name is nearly identical to
get_DW_UT_name from libiberty; but rather than simply replacing it, it
seemed better to have it work like the other DWARF constant
stringification functions -- return a string showing unrecognized
numeric forms rather than nullptr. (The previous code did include
numeric values for the recognized constants, but this seems to be not
that useful to me.)
2021-03-18 Tom Tromey <tromey@adacore.com>
* dwarf2/stringify.c (dwarf_unit_type_name): New function. Use
get_DW_UT_name.
* dwarf2/stringify.h (dwarf_unit_type_name): Declare.
* dwarf2/comp-unit.c (dwarf_unit_type_name): Remove.
The small example for gdb.Parameter.get_set_string does not return a
string. The documentation is very clear that this method must return
a string, and indeed, inspecting the code in gdb/python/py-param.c
shows that a string return value is required (if an exception is not
thrown).
While inspecting the code in gdb/python/py-param.c I noticed that the
comment for the C++ code that invokes the Python get_set_string method
is wrong, so I updated that too.
gdb/ChangeLog:
* python/py-param.c (get_set_value): Update header comment.
gdb/doc/ChangeLog:
* python.texinfo (Parameters In Python): Return empty string in
small example code.
PR 27478
* readelf.c (dump_section_as_strings): Mention separate filename.
(dump_section_as_bytes): Likewise.
(dump_section_as_ctf): Likewise.
(initialise_dumkps_byname): Only issue a warning for missing
sections if processing the main file.
(process_section_contents): Only issue a warning for unsumped
section numbers in the main file.
(initialise_dump_sects): New function. Contains code extracted
from ...
(process_object): ... here. Also call initialise_dump_sects for
separate files.
The previous commit started to error-check the lookup of
ctf_type_encoding for the underlying type that is internally done when
carrying out a ctf_type_encoding on a slice.
Unfortunately, enums have no encoding, so this has historically been
returning an error (which is ignored) and then populating the cte_format
with uninitialized data. Now the error is not ignored, this is
returning an error, which breaks linking of CTF containing bitfields of
enumerated type.
CTF format v3 does not record the actual underlying type of a enum, but
we can mock up something that is not *too* wrong, and that is at any
rate better than uninitialized data.
ld/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* testsuite/ld-ctf/slice.c: Check slices of enums too.
* testsuite/ld-ctf/slice.d: Results adjusted.
libctf/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* ctf-types.c (ctf_type_encoding): Support, after a fashion, for enums.
* ctf-dump.c (ctf_dump_format_type): Do not report enums' degenerate
encoding.
Out-of-memory errors initializing the string atoms table were
disregarded (though they would have caused a segfault very shortly
afterwards). Errors hashing types during deduplication were only
reported if they happened on the output dict, which is almost never the
case (most errors are going to be on the dict we're working over, which
is going to be one of the inputs). (The error was detected in both
cases, but the errno was extracted from the wrong dict.)
libctf/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* ctf-dedup.c (ctf_dedup_rhash_type): Report errors on the input
dict properly.
* ctf-open.c (ctf_bufopen_internal): Report errors initializing
the atoms table.
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.
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.
This is the first tricky one, the first complex multi-entry vlen
containing strings. To handle this in vlen form, we have to handle
pending refs moving around on realloc.
We grow vlen regions using a new ctf_grow_vlen function, and iterate
through the existing enums every time a grow happens, telling the string
machinery the distance between the old and new vlen region and letting
it adjust the pending refs accordingly. (This avoids traversing all
outstanding refs to find the refs that need adjusting, at the cost of
having to traverse one enum: an obvious major performance win.)
Addition of enums themselves (and also structs/unions later) is a bit
trickier than earlier forms, because the type might be being promoted
from a forward, and forwards have no vlen: so we have to spot that and
create it if needed.
Serialization of enums simplifies down to just telling the string
machinery about the string refs; all the enum type-lookup code loses all
its dynamic member lookup complexity entirely.
A new test is added that iterates over (and gets values of) an enum with
enough members to force a round of vlen growth.
libctf/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* ctf-impl.h (ctf_dtdef_t) <dtd_vlen_alloc>: New.
(ctf_str_move_pending): Declare.
* ctf-string.c (ctf_str_add_ref_internal): Fix error return.
(ctf_str_move_pending): New.
* ctf-create.c (ctf_grow_vlen): New.
(ctf_dtd_delete): Zero out the vlen_alloc after free. Free the
vlen later: iterate over it and free enum name refs first.
(ctf_add_generic): Populate dtd_vlen_alloc from vlen.
(ctf_add_enum): populate the vlen; do it by hand if promoting
forwards.
(ctf_add_enumerator): Set up the vlen rather than the dmd. Expand
it as needed, repointing string refs via ctf_str_move_pending. Add
the enumerand names as pending strings.
* ctf-serialize.c (ctf_copy_emembers): Remove.
(ctf_emit_type_sect): Copy the vlen into place and ref the
strings.
* ctf-types.c (ctf_enum_next): The dynamic portion now uses
the same code as the non-dynamic.
(ctf_enum_name): Likewise.
(ctf_enum_value): Likewise.
* testsuite/libctf-lookup/enum-many-ctf.c: New test.
* testsuite/libctf-lookup/enum-many.lk: New test.
The preceding change revealed a new bug: the string table is sorted for
better compression, so repeated serialization with type (or member)
additions in the middle can move strings around. But every
serialization flushes the set of refs (the memory locations that are
automatically updated with a final string offset when the strtab is
updated), so if we are not to have string offsets go stale, we must do
all ref additions within the serialization code (which walks the
complete set of types and symbols anyway). Unfortunately, we were adding
one ref in another place: the type name in the dynamic type definitions,
which has a ref added to it by ctf_add_generic.
So adding a type, serializing (via, say, one of the ctf_write
functions), adding another type with a name that sorts earlier, and
serializing again will corrupt the name of the first type because it no
longer had a ref pointing to its dtd entry's name when its string offset
was shifted later in the strtab to mae way for the other type.
To ensure that we don't miss strings, we also maintain a set of *pending
refs* that will be added later (during serialization), and remove
entries from that set when the ref is finally added. We always use
ctf_str_add_pending outside ctf-serialize.c, ensure that ctf_serialize
adds all strtab offsets as refs (even those in the dtds) on every
serialization, and mandate that no refs are live on entry to
ctf_serialize and that all pending refs are gone before strtab
finalization. (Of necessity ctf_serialize has to traverse all strtab
offsets in the dtds in order to serialize them, so adding them as refs
at the same time is easy.)
(Note that we still can't erase unused atoms when we roll back, though
we can erase unused refs: members and enums are still not removed by
rollbacks and might reference strings added after the snapshot.)
libctf/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* ctf-hash.c (ctf_dynset_elements): New.
* ctf-impl.h (ctf_dynset_elements): Declare it.
(ctf_str_add_pending): Likewise.
(ctf_dict_t) <ctf_str_pending_ref>: New, set of refs that must be
added during serialization.
* ctf-string.c (ctf_str_create_atoms): Initialize it.
(CTF_STR_ADD_REF): New flag.
(CTF_STR_MAKE_PROVISIONAL): Likewise.
(CTF_STR_PENDING_REF): Likewise.
(ctf_str_add_ref_internal): Take a flags word rather than int
params. Populate, and clear out, ctf_str_pending_ref.
(ctf_str_add): Adjust accordingly.
(ctf_str_add_external): Likewise.
(ctf_str_add_pending): New.
(ctf_str_remove_ref): Also remove the potential ref if it is a
pending ref.
* ctf-serialize.c (ctf_serialize): Prohibit addition of strings
with ctf_str_add_ref before serialization. Ensure that the
ctf_str_pending_ref set is empty before strtab finalization.
(ctf_emit_type_sect): Add a ref to the ctt_name.
* ctf-create.c (ctf_add_generic): Add the ctt_name as a pending
ref.
* testsuite/libctf-writable/reserialize-strtab-corruption.*: New test.
One pattern which is rarely done in libctf but which is meant to work is
this:
ctf_create();
ctf_add_*(); // add stuff
ctf_type_*() // look stuff up
ctf_write_*();
ctf_add_*(); // should still work
ctf_type_*() // so should this
ctf_write_*(); // and this
i.e., writing out a dict should not break it and you should be able to
do everything you could do with it before, including writing it out
again.
Unfortunately this has been broken for a while because the field which
indicates the maximum valid type ID was not preserved across
serialization: so type additions after serialization would overwrite
types (obviously disastrous) and type lookups would just fail.
Fix trivial.
libctf/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* ctf-serialize.c (ctf_serialize): Preserve ctf_typemax across
serialization.
This stops problems parallel-installing if a relink of libctf is needed.
Also adds corresponding install-strip dependencies.
ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
PR libctf/27482
* Makefile.def: Add install-bfd dependencies for install-libctf and
install-ld, and install-strip-bfd dependencies for
install-strip-libctf and install-strip-ld; move the install-ld
dependency on install-libctf to join it.
* Makefile.in: Regenerated.
One more member vanishes from the dtd_u, leaving only the member for
struct/union/enum members.
There's not much to do here, since as of commit afd78bd6f0 we use
the same representation (type sizes, etc) in the dtu_argv as we will
use in the final vlen, with one exception: the vlen has alignment
padding, and the dtu_argv did not. Simplify things by adding suitable
padding in both cases.
libctf/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* ctf-impl.h (ctf_dtdef_t) <dtd_u.dtu_argv>: Remove.
* ctf-create.c (ctf_dtd_delete): No longer free it.
(ctf_add_function): Use the dtd_vlen, not dtu_argv. Properly align.
* ctf-serialize.c (ctf_emit_type_sect): Just copy the dtd_vlen.
* ctf-types.c (ctf_func_type_info): Just use the vlen.
(ctf_func_type_args): Likewise.
This is even simpler than ints, floats and slices, with the only extra
complication being the need to manually transfer the array parameter in
the rarely-used function ctf_set_array. (Arrays are unique in libctf in
that they can be modified post facto, not just created and appended to.
I'm not sure why they got this exemption, but it's easy to maintain.)
libctf/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* ctf-impl.h (ctf_dtdef_t) <dtd_u.dtu_arr>: Remove.
* ctf-create.c (ctf_add_array): Use the dtd_vlen, not dtu_arr.
(ctf_set_array): Likewise.
* ctf-serialize.c (ctf_emit_type_sect): Just copy the dtd_vlen.
* ctf-types.c (ctf_array_info): Just use the vlen.
This series eliminates a lot of special-case code to handle dynamic
types (types added to writable dicts and not yet serialized).
Historically, when such types have variable-length data in their final
CTF representations, libctf has always worked by adding such types to a
special union (ctf_dtdef_t.dtd_u) in the dynamic type definition
structure, then picking the members out of this structure at
serialization time and packing them into their final form.
This has the advantage that the ctf_add_* code doesn't need to know
anything about the final CTF representation, but the significant
disadvantage that all code that looks up types in any way needs two code
paths, one for dynamic types, one for all others. Historically libctf
"handled" this by not supporting most type lookups on dynamic types at
all until ctf_update was called to do a complete reserialization of the
entire dict (it didn't emit an error, it just emitted wrong results).
Since commit 676c3ecbad, which eliminated ctf_update in favour of
the internal-only ctf_serialize function, all the type-lookup paths
grew an extra branch to handle dynamic types.
We can eliminate this branch again by dropping the dtd_u stuff and
simply writing out the vlen in (close to) its final form at ctf_add_*
time: type lookup for types using this approach is then identical for
types in writable dicts and types that are in read-only ones, and
serialization is also simplified (we just need to write out the vlen
we already created).
The only complexity lies in type kinds for which multiple
vlen representations are valid depending on properties of the type,
e.g. structures. But we can start simple, adjusting ints, floats,
and slices to work this way, and leaving everything else as is.
libctf/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* ctf-impl.h (ctf_dtdef_t) <dtd_u.dtu_enc>: Remove.
<dtd_u.dtu_slice>: Likewise.
<dtd_vlen>: New.
* ctf-create.c (ctf_add_generic): Perhaps allocate it. All
callers adjusted.
(ctf_dtd_delete): Free it.
(ctf_add_slice): Use the dtd_vlen, not dtu_enc.
(ctf_add_encoded): Likewise. Assert that this must be an int or
float.
* ctf-serialize.c (ctf_emit_type_sect): Just copy the dtd_vlen.
* ctf-dedup.c (ctf_dedup_rhash_type): Use the dtd_vlen, not
dtu_slice.
* ctf-types.c (ctf_type_reference): Likewise.
(ctf_type_encoding): Remove most dynamic-type-specific code: just
get the vlen from the right place. Report failure to look up the
underlying type's encoding.
It's formatted like this:
do
{
...
}
while (...);
Not like this:
do
{
...
} while (...);
or this:
do {
...
} while (...);
We used both in various places in libctf. Fixing it necessitated some
light reindentation.
libctf/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* ctf-archive.c (ctf_archive_next): GNU style fix for do {} while.
* ctf-dedup.c (ctf_dedup_rhash_type): Likewise.
(ctf_dedup_rwalk_one_output_mapping): Likewise.
* ctf-dump.c (ctf_dump_format_type): Likewise.
* ctf-lookup.c (ctf_symbol_next): Likewise.
* swap.h (swap_thing): Likewise.
ctf_serialize and its various pieces may be split out into a separate
file now, but ctf_serialize is still far too long and disordered, mixing
header initialization, sizing of multiple CTF sections, sorting and
emission of multiple CTF sections, strtab construction and ctf_dict_t
copying into a single ugly organically-grown mess.
Fix the worst of this by migrating all section sizing and emission into
separate functions, two per section (or class of section in the case of
the symtypetabs). Only the variable section is now sized and emitted
directly in ctf_serialize (because it only takes about three lines to do
so).
The section sizes themselves are still maintained by ctf_serialize so
that it can work out the header offsets, but ctf_symtypetab_sect_sizes
and ctf_emit_symtypetab_sects share a lot of extra state: migrate that
into a shared structure, emit_symtypetab_state_t.
(Test results unchanged.)
libctf/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* ctf-serialize.c: General reshuffling, and...
(emit_symtypetab_state_t): New, migrated from
local variables in ctf_serialize.
(ctf_serialize): Split out most section sizing and
emission.
(ctf_symtypetab_sect_sizes): New (split out).
(ctf_emit_symtypetab_sects): Likewise.
(ctf_type_sect_size): Likewise.
(ctf_emit_type_sect): Likewise.
It is perfectly possible to have dynamically allocated data owned by a
specific dict: you just have to teach ctf_serialize about it.
libctf/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* ctf-impl.h (ctf_dict_t): Fix comment.
The code to serialize CTF dicts just gets bigger and bigger as the
dictionary's complexity grows: adding symtypetabs almost doubled it on
its own. It's long past time to split this out into its own source
file, accompanied by the functions that do the actual writeout.
This leaves ctf-create.c populated exclusively by functions related to
actual writable dict creation (ctf_add_*, ctf_create etc), and leaves
both files a much more reasonable size.
libctf/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* ctf-create.c (symtypetab_delete_nonstatic_vars): Move
into ctf-serialize.c.
(ctf_symtab_skippable): Likewise.
(CTF_SYMTYPETAB_EMIT_FUNCTION): Likewise.
(CTF_SYMTYPETAB_EMIT_PAD): Likewise.
(CTF_SYMTYPETAB_FORCE_INDEXED): Likewise.
(symtypetab_density): Likewise.
(emit_symtypetab): Likewise.
(emit_symtypetab_index): Likewise.
(ctf_copy_smembers): Likewise.
(ctf_copy_lmembers): Likewise.
(ctf_copy_emembers): Likewise.
(ctf_sort_var): Likewise.
(ctf_serialize): Likewise.
(ctf_gzwrite): Likewise.
(ctf_compress_write): Likewise.
(ctf_write_mem): Likewise.
(ctf_write): Likewise.
* ctf-serialize.c: New file.
* Makefile.am (libctf_nobfd_la_SOURCES): Add it.
* Makefile.in: Regenerate.
ctf-link.c is unnecessarily confusing because ctf_link_lazy_open is
positioned near functions that have nothing to do with opening files.
Move it around, and fix some tabdamage that's crept in lately.
libctf/ChangeLog
2021-03-18 Nick Alcock <nick.alcock@oracle.com>
* ctf-link.c (ctf_link_lazy_open): Move up in the file, to near
ctf_link_add_ctf.
* ctf-lookup.c (ctf_lookup_symbol_idx): Repair tabdamage.
(ctf_lookup_by_sym_or_name): Likewise.
* testsuite/libctf-lookup/struct-iteration.c: Likewise.
* testsuite/libctf-regression/type-add-unnamed-struct.c: Likewise.
If we reach the modified line, resume_target is necessarily nullptr,
because of the check at the beginning of the function. So we'll
necessarily iterate on all non-exited inferiors (across all targets),
which is what we want. So just remove the unnecessary argument.
gdb/ChangeLog:
* infrun.c (check_multi_target_resumption): Remove argument to
all_non_exited_inferiors.
Change-Id: If95704915dca19599d5f7f4732bbd6ccd20bf6b4
A WIP patch series broke the use case of doing "run" or "attach" while
the program is running, but it wasn't caught by the testsuite, which
means it's not covered. Add a test for that.
gdb/testsuite/ChangeLog:
* gdb.base/run-attach-while-running.exp: New.
* gdb.base/run-attach-while-running.c: New.
Change-Id: I77f098ec0b28dc2d4575ea80e941f6a75273e431
PR 27533
* readelf.c (process_section_contents): Only dump debug
information for separate files unless process_links is enabled.
(process_object): Always call process_section_contents for
separate info files.
With "gcc version 10.2.0 (GCC)" on cygwin, I get this build error:
CXX windows-nat.o
In file included from ../../gdb/../gdbsupport/common-defs.h:129,
from ../../gdb/defs.h:28,
from ../../gdb/windows-nat.c:24:
../../gdb/windows-nat.c: In function 'void windows_init_thread_list()':
../../gdb/windows-nat.c:513:17: error: zero-length gnu_printf format string [-Werror=format-zero-length]
513 | DEBUG_EVENTS ("");
| ^~
../../gdb/../gdbsupport/common-debug.h:65:43: note: in definition of macro 'debug_prefixed_printf_cond'
65 | debug_prefixed_printf (module, __func__, fmt, ##__VA_ARGS__); \
| ^~~
../../gdb/windows-nat.c:513:3: note: in expansion of macro 'DEBUG_EVENTS'
513 | DEBUG_EVENTS ("");
| ^~~~~~~~~~~~
cc1plus: all warnings being treated as errors
This was introduced in 4ef367bffd, which removed
the function name from this debug message:
- DEBUG_EVENTS (("gdb: windows_init_thread_list\n"));
+ DEBUG_EVENTS ("");
DEBUG_EVENTS now always includes the function name, so just add a "called"
message to fix the compile error.
gdb/ChangeLog:
2021-03-16 Christian Biesinger <cbiesinger@google.com>
* windows-nat.c (windows_init_thread_list): Add message to
debug log.
* peXXigen.c (_bfd_XXi_swap_aux_out): Avoid potential buffer
overrun by using sizeof of the destination x_fname field as the
limit for a memcpy.
* coff/internal.h (struct internal_auxent): Fix a couple of typos
in comment describing the x_fname field.
This commit:
commit d1cab9876d
Date: Tue Sep 15 11:08:56 2020 -0600
Don't use gdb_py_long_from_ulongest
Introduced a regression when GDB is compiled with Python 2. The frame
filter API expects the gdb.FrameDecorator.function () method to return
either a string (the name of a function) or an address, which GDB then
uses to lookup a msymbol.
If the address returned from gdb.FrameDecorator.function () comes from
gdb.Frame.pc () then before the above commit we would always expect to
see a PyLong object.
After the above commit we might (on Python 2) get a PyInt object.
The GDB code does not expect to see a PyInt, and only checks for a
PyLong, we then see an error message like:
RuntimeError: FrameDecorator.function: expecting a String, integer or None.
This commit just adds an additional call to PyInt_Check which handle
the missing case.
I had already written a test case to cover this issue before spotting
that the gdb.python/py-framefilter.exp test also triggers this
failure. As the new test case is slightly different I have kept it
in.
The new test forces the behaviour of gdb.FrameDecorator.function
returning an address. The reason the existing test case hits this is
due to the behaviour of the builtin gdb.FrameDecorator base class. If
the base class behaviour ever changed then the return an address case
would only be tested by the new test case.
gdb/ChangeLog:
* python/py-framefilter.c (py_print_frame): Use PyInt_Check as
well as PyLong_Check for Python 2.
gdb/testsuite/ChangeLog:
* gdb.python/py-framefilter-addr.c: New file.
* gdb.python/py-framefilter-addr.exp: New file.
* gdb.python/py-framefilter-addr.py: New file.
Resolve all of the duplicate test names in the gdb.threads/*.exp set
of tests (that I see). Nothing very exciting here, mostly either
giving tests explicit testnames, or adding with_test_prefix.
The only interesting one is gdb.threads/execl.exp, I believe the
duplicate test name was caused by an actual duplicate test. I've
remove the simpler form of the test. I don't believe we've lost any
test coverage with this change.
gdb/testsuite/ChangeLog:
* gdb.threads/execl.exp: Remove duplicate 'info threads' test.
Make use of $gdb_test_name instead of creating a separate $test
variable.
* gdb.threads/print-threads.exp: Add a with_test_prefix instead of
adding a '($name)' at the end of each test. This also catches the
one place where '($name)' was missing, and so caused a duplicate
test name.
* gdb.threads/queue-signal.exp: Give tests unique names to avoid
duplicate test names based on the command being tested.
* gdb.threads/signal-command-multiple-signals-pending.exp:
Likewise.
* lib/gdb.exp (gdb_compile_shlib_pthreads): Tweak test name to
avoid duplicate testnames when a test script uses this proc and
also gdb_compile_pthreads.
* lib/prelink-support.exp (build_executable_own_libs): Use
with_test_prefix to avoid duplicate test names when we call
build_executable twice.
PR build/27579 points out that the expression rewrite series
introduced a build failure with GCC 4.8.2. The bug is that there's no
std::hash specialization for enum exp_opcode. This patch fixes the
problem by using gdb::hash_enum.
2021-03-15 Tom Tromey <tromey@adacore.com>
PR build/27579:
* rust-exp.y (maker_map): Use gdb::hash_enum.
* stap-probe.c (stap_maker_map): Use gdb::hash_enum.
This printout in create_debug_type_hash_table has an unexpected colon at
the end, remove it:
[dwarf-read] create_debug_type_hash_table: Reading .debug_info for /home/simark/build/binutils-gdb/gdb/a.out:
gdb/ChangeLog:
* dwarf2/read.c (create_debug_type_hash_table): Remove colon at
end of debug print.
Change-Id: I2d707248249daf4d8b6fa8e7064acdc56c90f2dd
I added these printouts while working on 27541. I won't have a fix for
that right now, but I thought that it would be useful to merge them
upstream, as they help understand what happens in that function.
gdb/ChangeLog:
* dwarf2/read.c (dwarf2_initialize_objfile): Add debug prints.
Change-Id: I790c0d53383327038cb5dd705f74c8c978e0a7ec
I noticed that this parameter was unused, remove it.
gdb/ChangeLog:
* dwarf2/read.c (dw2_get_file_names_reader): Remove info_ptr
parameter, adjust caller.
Change-Id: I2a741766a0c658c22c512590aeffdd07391c869c
My previous Ada patches introduced a bug that I found after checkin.
I had incorrectly implemented unary +. There was a test for the
overloaded case, but no test for the ordinary case.
This patch adds the tests and fixes the bug.
Tested on x86-64 Fedora 32.
gdb/ChangeLog
2021-03-15 Tom Tromey <tromey@adacore.com>
* ada-exp.y (simple_exp): Always push a result for unary '+'.
gdb/testsuite/ChangeLog
2021-03-15 Tom Tromey <tromey@adacore.com>
* gdb.ada/fixed_points.exp: Add tests of unary + and -.
Internal testing revealed yet another Ada regression from the
expression rewrite. In this case, indirection did not use the Ada
varsize limit. The old code relied on the expression resolution
process to evaluate this subexpression with EVAL_AVOID_SIDE_EFFECTS in
order to get this error. However, this isn't always done in the new
approach; so this patch introduces another call to
ada_ensure_varsize_limit in the appropriate spot.
As with the earlier patches, this path was not tested in-tree, so this
patch also updates a test.
gdb/ChangeLog
2021-03-15 Tom Tromey <tromey@adacore.com>
* ada-lang.c (ada_unop_ind_operation::evaluate): Call
ada_ensure_varsize_limit.
gdb/testsuite/ChangeLog
2021-03-15 Tom Tromey <tromey@adacore.com>
* gdb.ada/varsize_limit.exp: Add new test.
* gdb.ada/varsize_limit/vsizelim.adb: Update.
In the expression rewrite, I neglected to carry over support for Ada
operator overloading. It turns out that there were no tests for this
in-tree.
This patch adds support for operator overloading, and adds the missing
test.
gdb/ChangeLog
2021-03-15 Tom Tromey <tromey@adacore.com>
* ada-lang.c (numeric_type_p, integer_type_p): Return true for
fixed-point.
* ada-exp.y (maybe_overload): New function.
(ada_wrap_overload): New function.
(ada_un_wrap2, ada_wrap2, ada_wrap_op): Use maybe_overload.
(exp1, simple_exp, relation, and_exp, and_then_exp, or_exp)
(or_else_exp, xor_exp, primary): Update.
gdb/testsuite/ChangeLog
2021-03-15 Tom Tromey <tromey@adacore.com>
* gdb.ada/operator_call/twovecs.ads: New file.
* gdb.ada/operator_call/twovecs.adb: New file.
* gdb.ada/operator_call/opcall.adb: New file.
* gdb.ada/operator_call.exp: New file.
This fixes PR ada/27545, which points out that a test in
gdb.ada/tagged.exp started failing due to the expression rewrite. I
didn't notice this failure because my system gcc-gnat debuginfo was
out of date, and so the test was already failing in the baseline.
Previously, the OP_VAR_VALUE case in ada_evaluate_subexp ended up
doing a recursive call:
arg1 = evaluate_subexp (nullptr, exp, pos, EVAL_NORMAL);
However, during the rewrite I missed this fact and had the new code
call the superclass implementation.
This patch fixes the bug by changing this code to use a recursive call
instead.
gdb/ChangeLog
2021-03-15 Tom Tromey <tromey@adacore.com>
PR ada/27545:
* ada-lang.c (ada_var_value_operation::evaluate): Use recursive
call for tagged type.
The expression rewrite missed an Ada resolution case. GDB previously
knew how to disambiguate the right hand side of an assignment, but now
it does not.
This patch fixes the problem and adds the missing test case.
gdb/ChangeLog
2021-03-15 Tom Tromey <tromey@adacore.com>
* ada-exp.y (exp1): Handle resolution of the right hand side of an
assignment.
gdb/testsuite/ChangeLog
2021-03-15 Tom Tromey <tromey@adacore.com>
* gdb.ada/enums_overload/enums_overload_main.adb: New file.
* gdb.ada/enums_overload/enums_overload.ads: New file.
* gdb.ada/enums_overload/enums_overload.adb: New file.
* gdb.ada/enums_overload.exp: New file.
The expression rewrite caused a regression in the internal AdaCore
test suite. The bug was that I had dropped a bit of code from
aggregate assignment -- assign_aggregate used to return the container,
which I thought was redundant, but which can actually change during
the call. There was no test for this case in the tree, so I've added
one.
gdb/ChangeLog
2021-03-15 Tom Tromey <tromey@adacore.com>
* ada-lang.c (ada_aggregate_operation::assign_aggregate): Return
container.
(ada_assign_operation::evaluate): Update.
* ada-exp.h (class ada_aggregate_operation) <assign_aggregate>:
Change return type.
gdb/testsuite/ChangeLog
2021-03-15 Tom Tromey <tromey@adacore.com>
* gdb.ada/assign_arr/target_wrapper.ads (IArray, Put, Do_Nothing):
Declare.
* gdb.ada/assign_arr/target_wrapper.adb: New file.
* gdb.ada/assign_arr/main_p324_051.adb (IValue): New variable.
Call Put.
* gdb.ada/assign_arr.exp: Update.
PR 27487
* nm.c (FORMAT_JUST_SYMBOLS): Define.
(struct optput_fns): Add entry for FORMAT_JUST_SYMBOLS.
(long_options): Add just-symbols.
(set_output_format): Add support for just-symbols.
(get_print_format): Likewise.
(do_not_print_object_filename): New function.
(do_not_print_archive_filename): New function.
(do_not_print_archive_member): New function.
(do_not_print_symbol_filename): New function.
(just_print_symbol_name): New function.
(main): Handle --just-symbols.
* NEWS: Mention the new feature.
* doc/binutils.texi: Document the new feature.
Intel Fortran compilers emit the following DWARF for gdb.fortran/complex.f90:
0x00000071: DW_TAG_base_type
DW_AT_name ("COMPLEX*32")
DW_AT_encoding (DW_ATE_complex_float)
DW_AT_byte_size (0x20)
0x00000078: DW_TAG_base_type
DW_AT_name ("REAL*16")
DW_AT_encoding (DW_ATE_float)
DW_AT_byte_size (0x10)
This results in GDB not reading the right values, as it wrongly assumes the
default floatformat "floatformat_i387_ext" instead of
"floatformat_ia64_quad_little".
gdb/ChangeLog:
2021-03-15 Felix Willgerodt <felix.willgerodt@intel.com>
* i386-tdep.c (i386_floatformat_for_type): Add COMPLEX*32 and REAL*16.
The allocation of reloc_d doesn't take reloc_s->size into account. There
is already padding being emitted up to the allocated size. While
reloc_s->size ought to still be zero at this point anyway (and hence the
code being deleted would have been just dead), don't risk writing past
the actual allocation.
The current mechanism by which the Python gdb.current_objfile is
maintained does not allow for nested auto-load events. It is assumed
that once an auto-load script has finished loading then the current
objfile should be set back to NULL. In a nested situation, we should
be restoring the previous value.
We already have an RAII class to handle save/restore type behaviour,
so lets just switch to use that.
The test is a little contrived, but is simple enough, and triggers the
bug. The real use case might involve the auto-load script calling
functions (either in the just-loaded object file, or in the main
executable), which in turn trigger further auto-loads to occur.
gdb/ChangeLog:
* python/python.c (gdbpy_source_objfile_script): Use
make_scoped_restore to restore gdbpy_current_objfile.
(gdbpy_execute_objfile_script): Likewise.
gdb/testsuite/ChangeLog:
* gdb.python/py-auto-load-chaining-f1.c: New file.
* gdb.python/py-auto-load-chaining-f1.o-gdb.py: New file.
* gdb.python/py-auto-load-chaining-f2.c: New file.
* gdb.python/py-auto-load-chaining-f2.o-gdb.py: New file.
* gdb.python/py-auto-load-chaining.c: New file.
* gdb.python/py-auto-load-chaining.exp: New file.
read_attribute_value has a local cu_header variable, but then some
spots in the function use cu->header instead. It seems better to me
to prefer the local everywhere, so this patch makes this change.
gdb/ChangeLog
2021-03-14 Tom Tromey <tom@tromey.com>
* dwarf2/read.c (read_attribute_value): Use cu_header
consistently.
