The pattern for using execute_command_to_string is:
...
std::string output;
output = execute_fn_to_string (fn, term_out);
...
This results in a problem when using it in a try/catch:
...
try
{
output = execute_fn_to_string (fn, term_out)
}
catch (const gdb_exception &e)
{
/* Use output. */
}
...
If an expection was thrown during execute_fn_to_string, then the output
remains unassigned, while it could be worthwhile to known what output was
generated by gdb before the expection was thrown.
Fix this by returning the string using a parameter instead:
...
execute_fn_to_string (output, fn, term_out)
...
Also add a variant without string parameter, to support places where the
function is used while ignoring the result:
...
execute_fn_to_string (fn, term_out)
...
Tested on x86_64-linux.
Consider the gdb output:
...
27 return SYSCALL_CANCEL (nanosleep, requested_time, remaining);^M
(gdb) ^M
Thread 2 "run-attach-whil" stopped.^M
...
When trying to match the gdb prompt using gdb_test which uses '$gdb_prompt $',
it may pass or fail.
This sort of thing needs to be fixed (see commit b0e2f96b56b), but there's
currently no way to reliably find this type of FAILs.
We have check-read1, but that one actually make the test pass reliably.
We need something like the opposite of check-read1: something that makes
expect read a bit slower, or more exhaustively.
Add a new test target check-readmore that implements this.
There are two methods of implementing this in read1.c:
- the first method waits a bit before doing a read
- the second method does a read and then decides whether to
return or to wait a bit and do another read, and so on.
The second method is potentially faster, has less risc of timeout and could
potentially detect more problems. The first method has a simpler
implementation.
The second method is enabled by default. The default waiting period is 10
miliseconds.
The first method can be enabled using:
...
$ export READMORE_METHOD=1
...
and the waiting period can be specified in miliseconds using:
...
$ export READMORE_SLEEP=9
...
Also a log file can be specified using:
...
$ export READMORE_LOG=$(pwd -P)/LOG
...
Tested on x86_64-linux.
Testing with check-readmore showed these regressions:
...
FAIL: gdb.base/bp-cmds-continue-ctrl-c.exp: run: stop with control-c (continue)
FAIL: gdb.base/bp-cmds-continue-ctrl-c.exp: attach: stop with control-c (continue)
...
I have not been able to find a problem in the test-case, and I think it's the
nature of both the test-case and readmore that makes it run longer. Make
these pass by increasing the alarm timeout from 60 to 120 seconds.
Bug: https://sourceware.org/bugzilla/show_bug.cgi?id=27957
When running these test-cases:
- gdb.fortran/info-modules.exp
- gdb.fortran/module.exp
- gdb.mi/mi-fortran-modules.exp
in conjunction with:
...
$ stress -c $(($(cat /proc/cpuinfo | grep -c "^processor") + 1))
...
I run into timeouts.
Fix this by using:
- "set auto-solib-add off" to avoid symbols of shared libs
(which doesn't work for libc, now that libpthread_name_p has been
updated to match libc)
- "nosharedlibrary" to avoid symbols of libc
Tested on x86_64-linux.
Bug: https://sourceware.org/bugzilla/show_bug.cgi?id=28133
When running test-case gdb.base/info-types-c++.exp in conjunction with:
...
$ stress -c $(($(cat /proc/cpuinfo | grep -c "^processor") + 1))
...
we get:
...
FAIL: gdb.base/info-types-c++.exp: info types (timeout)
...
Fix this by setting auto-solib-add to off.
Tested on x86_64-linux.
When running test-case gdb.base/info_sources_2.exp with check-read1, I run
into:
...
FAIL: gdb.base/info_sources_2.exp: args: : info sources (timeout)
...
Fix this by consuming a "$src1, $src2, ..., $srcn: line bit by bit rather than
as one whole line.
Also add the missing handling of "Objfile has no debug information".
Tested on x86_64-linux.
When running test-case gdb.mi/gdb2549.exp with check-read1, I run into:
...
FAIL: gdb.mi/gdb2549.exp: register values x (timeout)
...
Fix this by applying the same fix as for "register values t" in commit
478e490a4df "[gdb/testsuite] Fix gdb.mi/gdb2549.exp with check-read1".
Tested on x86_64-linux.
When running test-case gdb.base/bt-on-error-and-warning.exp with check-read1,
I run into:
...
(gdb) maint internal-error foobar^M
src/gdb/maint.c:82: internal-error: foobar^M
A problem internal to GDB has been detectedFAIL: \
gdb.base/bt-on-error-and-warning.exp: problem=internal-error, mode=on: \
scan for backtrace (GDB internal error)
Resyncing due to internal error.
,^M
...
The corresponding gdb_test_multiple in the test-case contains:
...
-early -re "^A problem internal to GDB has been detected,\r\n" {
incr header_lines
exp_continue
}
...
but instead this one triggers in gdb_test_multiple:
...
-re ".*A problem internal to GDB has been detected" {
fail "$message (GDB internal error)"
gdb_internal_error_resync
set result -1
}
...
Fix this by likewise shortening the regexp to before the comma.
Tested on x86_64-linux.
When running test-case gdb.dwarf2/dw2-restrict.exp on openSUSE Leap 15.2 with
gcc-PIE installed (switching compiler default to -fPIE/-pie), I get:
...
gdb compile failed, ld: outputs/gdb.dwarf2/dw2-restrict/dw2-restrict0.o: \
warning: relocation in read-only section `.text'
ld: warning: creating DT_TEXTREL in a PIE
UNTESTED: gdb.dwarf2/dw2-restrict.exp: failed to prepare
...
This is due to using a hardcoded .S file that was generated with -fno-PIE.
Fix this by adding the missing nopie.
Likewise in gdb.arch/amd64-tailcall-noret.exp.
Tested on x86_64-linux.
When running test-case gdb.threads/check-libthread-db.exp on openSUSE
Tumbleweed (with glibc 2.34) I get:
...
(gdb) continue^M
Continuing.^M
[Thread debugging using libthread_db enabled]^M
Using host libthread_db library "/lib64/libthread_db.so.1".^M
Stopped due to shared library event:^M
Inferior loaded /lib64/libm.so.6^M
/lib64/libc.so.6^M
(gdb) FAIL: gdb.threads/check-libthread-db.exp: user-initiated check: continue
...
The check expect the inferior to load libpthread, but since glibc 2.34
libpthread has been integrated into glibc, and consequently it's no longer
a dependency:
...
$ ldd outputs/gdb.threads/check-libthread-db/check-libthread-db
linux-vdso.so.1 (0x00007ffe4cae4000)
libm.so.6 => /lib64/libm.so.6 (0x00007f167c77c000)
libc.so.6 => /lib64/libc.so.6 (0x00007f167c572000)
/lib64/ld-linux-x86-64.so.2 (0x00007f167c86e000)
...
Fix this by updating the regexp to expect libpthread or libc.
Tested on x86_64-linux.
Add accessors for the various location values in struct field. This
lets us assert that when we get a location value of a certain kind (say,
bitpos), the field's location indeed contains a value of that kind.
Remove the SET_FIELD_* macros, instead use the new setters directly.
Update the FIELD_* macros used to access field locations to go through
the getters. They will be removed in a subsequent patch.
There are places where the FIELD_* macros are used on call_site_target
structures, because it contains members of the same name (loc_kind and
loc). For now, I have replicated the getters/setters in
call_site_target. But we could perhaps eventually factor them in a
"location" structure that can be used at both places.
Note that the field structure, being zero-initialized, defaults to a
bitpos location with value 0. While writing this patch, I tried to make
it default to an "unset" location, to catch places where we would miss
setting a field's location. However, I found that some places relied on
the default being "bitpos 0", so I left it as-is. This change could
always be done as follow-up work, making these places explicitly set the
"bitpos 0" location.
I found two issues to fix:
- I got some failures in the gdb.base/infcall-nested-structs-c++.exp
test. They were caused by two functions in amd64-tdep.c using
TYPE_FIELD_BITPOS before checking if the location is of the bitpos
kind, which they do indirectly through `field_is_static`. Simply
move getting the bitpos below the field_is_static call.
- I got a failure in gdb.xml/tdesc-regs.exp. It turns out that in
make_gdb_type_enum, we set enum field values using SET_FIELD_BITPOS,
and later access them through FIELD_ENUMVAL. Fix that by using
set_loc_enumval to set the value.
Change-Id: I53d3734916c46457576ba11dd77df4049d2fc1e8
Add aliases for the non-immediate mnemonics of b{set,clr,inv,ext} to
yencode the respective immediate insn b{set,clr,inv,ext}i when the
second source operand is an immediate.
2021-01-11 Philipp Tomsich <philipp.tomsich@vrull.eu>
gas/
* testsuite/gas/riscv/b-ext.d: Add tests.
* testsuite/gas/riscv/b-ext.s: Likewise.
* testsuite/gas/riscv/b-ext-64.d: Likewise.
* testsuite/gas/riscv/b-ext-64.s: Likewise.
opcodes/
* riscv-opc.c (riscv_opcodes): Add aliases for Zbs.
Suggested-by: Jan Beulich <jbeulich@suse.com>
Signed-off-by: Philipp Tomsich <philipp.tomsich@vrull.eu>
2021-10-06 Philipp Tomsich <philipp.tomsich@vrull.eu>
bfd/
* elfxx-riscv.c (riscv_supported_std_z_ext): Update the version
number for zba, zbb and zbc to 1.0.0
Signed-off-by: Philipp Tomsich <philipp.tomsich@vrull.eu>
Version-changes: 3
- Updated version numbers for zba, zbb and zbc to 1.0.0
The Zb[abc] opcodes are bundled just below the Privileged opcodes in
riscv_opcodes, possibly giving the appearance that they are part of
the Privileged spec for an uninitiated reader. This separates them
out and adds comments above each section to clearly identify them as
Zba, Zbb or Zbc opcodes.
2021-10-04 Philipp Tomsich <philipp.tomsich@vrull.eu>
opcodes/
* riscv-opc.c: Split of Zb[abc] instructions and add comments.
Signed-off-by: Philipp Tomsich <philipp.tomsich@vrull.eu>
XCOFF archives use a bi-directional linked list for file members. So
one member points to both the previous member and the next member.
Members may not be sequentially ordered in the file. This of course
is over-engineered nonsense and an attractive target for fuzzers.
(There is even a free list of members!) The testcase in PR28423 is an
XCOFF archive with one member pointing to itself, which results in
lots of bad behaviour. For example, "ar t" never terminates.
The use-after-free with "objdump -r" happens like this: The first
archive element is opened, its symbols are read and "canonicalized"
for objdump, then relocations are read and printed. Those relocations
use the canonicalized symbols, and also happen to be cached by the
coff bfd backend support. objdump frees the symbols. The next
archive element is then opened. This must be done before the first
element is closed, because finding the next element uses data held in
the currect element. Unfortunately the next element happens to be the
original, so we aren't opening, we're reopening a bfd which has cached
data. When the relocations are printed they use the cached copy
containing references to the freed canonical symbols.
This patch adds a little sanity checking to the XCOFF "open next
archive file" support, so that it rejects archive members pointing at
themselves. That is sufficient to cure this problem. Anything more
is overkill. If someone deliberately fuzzes an XCOFF archive with an
element loop then reports an "ar" bug when it runs forever, they will
find their bug report closed WONTFIX.
PR 28423
* coff-rs6000.c (_bfd_xcoff_read_ar_hdr): Save size occupied
by member name in areltdata.extra_size.
(_bfd_xcoff_openr_next_archived_file): Sanity check nextoff.
* coff64-rs6000.c (xcoff64_openr_next_archived_file): Call
_bfd_xcoff_openr_next_archived_file.
This fixes a bug in commit 5d9bbb73c1df. All fields preserved from a
bfd in struct bfd_preserve need to be cleared in bfd_reinit.
PR 28422
* format.c (bfd_reinit): Clear build_id.
Rather than reporting "memory exhausted", report "file truncated".
You can hit this error on small fuzzed object files, or on files that
are actually truncated. In either case sizes can be such that an out
of memory error is a little confusing.
* compress.c (bfd_get_full_section_contents): Set
bfd_error_file_truncated rather than bfd_error_no_memory when
section size exceeds file size.
On openSUSE tumbleweed I run into:
...
FAIL: gdb.base/annota1.exp: run until main breakpoint (timeout)
...
due to a message related to libthread_db:
...
^Z^Zstarting^M
[Thread debugging using libthread_db enabled]^M
Using host libthread_db library "/lib64/libthread_db.so.1".^M
^M
^Z^Zframes-invalid^M
...
which is not matched by the regexp.
Fix this by updating the regexp.
Tested on x86_64-linux.
The documentation for 'show print elements' contains the line:
If the number is 0, then the printing is unlimited.
However, this line is now out of date as can be seen by this GDB
session:
(gdb) set print elements 0
(gdb) show print elements
Limit on string chars or array elements to print is unlimited.
The value 0 does indeed mean unlimited, and this is described in the
'set print elements' section, however, for 'show print elements' the
user will never see the value 0, so lets just remove that bit from the
docs.
When running test-case gdb.tui/corefile-run.exp on openSUSE Tumbleweed,
I run into:
...
PASS: gdb.tui/corefile-run.exp: load corefile
FAIL: gdb.tui/corefile-run.exp: run until the end
...
What's going on is easier to see when also doing dump_screen if
check_contents passes, and inspecting state at the preceding PASS:
...
+-------------------------------------------------------------------------+
exec No process In: L?? PC: ??
[New LWP 16629]
[Thread debugging using libthread_db enabled]
Using host libthread_db library "/lib64/libthread_db.so.1".
Core was generated by `/data/gdb_versions/devel/build/gdb/testsuite/output
s/gdb.tui/corefile-run/corefi'.
Program terminated with signal SIGTRAP, Trace/breakpoint trap.
#0 main ()
--Type <RET> for more, q to quit, c to continue without paging--
...
The problem is that we're getting a pagination prompt, and the subsequent run
command is interpreted as an answer to that prompt.
Fix this by:
- detecting the gdb prompt in response to "load corefile", such that
we detect the failure earlier, and
- doing a "set pagination off" in Term::clean_restart.
Tested on x86_64-linux.
This fixes a situation where the COFF code allocated memory for
internal representaion arrays before reading the external file data.
That meant the allocation didn't have any sanity check against file
size.
PR 28402
* coffcode.h (buy_and_read): Malloc rather than alloc memory.
(coff_slurp_line_table): Read native line number info before
allocating memory for internal line number array. Adjust error
paths to suit. Remove now unnecessary line number count check.
(coff_slurp_reloc_table): Adjust to suit buy_and_read change.
The PR28401 testcase has a section named "", ie. an empty string.
This results in some silly behaviour in load_debug_section, and
dump_dwarf_section. Fix that. Note that this patch doesn't correct
the main complaint in PR28401, "failed to allocate", since malloc
failures on sections having huge bogus sizes are to be expected. We
can't safely catch all such cases by comparing with file size, for
example, where sections contain compressed data.
PR 28401
* objdump.c (load_debug_section): Don't attempt to retrieve
empty name sections.
(dump_dwarf_section): Likewise.
Currently, tui testing is rather verbose. When using these RUNTESTFLAGS to
pick up all tui tests (17 in total):
...
rtf=$(echo $(cd src/gdb/testsuite/; find gdb.* -type f -name *.exp* \
| xargs grep -l tuiterm_env) )
...
we have:
...
$ wc -l gdb.log
120592 gdb.log
...
Most of the output is related to controlling the tui screen, but that does
not give a top-level sense of how the test-case progresses.
Put differently: a lot of bandwith is used to describe how we arrive at a
certain tui screen state. But we don't actually always show the state we
arrive at, unless there's a FAIL.
And if there's say, a PASS that should actually be FAILing, it's hard to
detect.
Fix this by:
- dropping the -log on the call to verbose in _log. We still can get the
same info back using runtest -v.
- dumping the screen or box that we're checking, also when the test passes.
Brings down verbosity to something more reasonable:
...
$ wc -l gdb.log
3221 gdb.log
...
Tested on x86_64-linux.
The commit 702991711a91bd47b209289562843a11e7009396 (gdb: Have setter
and getter callbacks for settings) makes it possible for a setting not
to be backed by a memory buffer but use callback functions instead to
retrieve or set the setting's value.
An assertion was not properly updated to take into account that the
m_var member (which points to a memory buffer, if used) might be nullptr
if the setting uses callback functions. If the setting is backed by a
memory buffer, the m_var has to be non nullptr, which is already checked
before the pointer is dereferenced.
This commit removes this assertion as it is not valid anymore.
This makes the Ada-specific "varsize-limit" a synonym for
"max-value-size", and removes the Ada-specific checks of the limit.
I am not certain of the history here, but it seems to me that this
code is fully obsolete now. And, removing this makes it possible to
index large Ada arrays without triggering an error. A new test case
is included to demonstrate this.
This changes value_zero to create a lazy value. In many cases,
value_zero is called in expression evaluation to wrap a type in a
non-eval context. It seems senseless to allocate a buffer in these
cases.
A new 'is_zero' flag is added so we can preserve the existing
assertions in value_fetch_lazy.
A subsequent patch will add a test where creating a zero value would
fail, due to the variable size check. However, the contents of this
value are never needed, and so creating a lazy value avoids the error
case.
This adds an is_optimized_out function pointer to lval_funcs, and
changes value_optimized_out to call it. This new function lets gdb
determine if a value is optimized out without necessarily fetching the
value. This is needed for a subsequent patch, where an attempt to
access a lazy value would fail due to the value size limit -- however,
the access was only needed to determine the optimized-out state.
Since commit e36788d1354 "[gdb/testsuite] Fix handling of nr_args < 3 in
mi_gdb_test" we run into:
...
PASS: gdb.mi/mi-nsmoribund.exp: print done = 1
Expecting: ^(.*[^M
]+)?([^
]*^M
\*running,thread-id="[0-9]+"^M
\*running,thread-id="[0-9]+"^M
\*running,thread-id="[0-9]+"^M
\*running,thread-id="[0-9]+"^M
\*running,thread-id="[0-9]+"^M
\*running,thread-id="[0-9]+"^M
\*running,thread-id="[0-9]+"^M
\*running,thread-id="[0-9]+"^M
\*running,thread-id="[0-9]+"^M
\*running,thread-id="[0-9]+"[^M
]+[(]gdb[)] ^M
[ ]*)
103-exec-continue --all^M
=library-loaded,id="/lib64/libgcc_s.so.1",target-name="/lib64/libgcc_s.so.1",\
host-name="/lib64/libgcc_s.so.1",symbols-loaded="0",thread-group="i1",\
ranges=[{from="0x00007ffff22a5010",to="0x00007ffff22b6365"}]^M
103^running^M
*running,thread-id="5"^M
(gdb) ^M
FAIL: gdb.mi/mi-nsmoribund.exp: 103-exec-continue --all (unexpected output)
...
The regexp expect running messages for all threads, but we only get one for
thread 5.
The test-case uses non-stop mode, and when the exec-continue --all command is
issued, thread 5 is stopped and all other threads are running. Consequently,
only thread 5 is resumed, and reported as running.
Fix this by updating the regexp.
Tested on x86_64-linux.
When a user creates a gdb.Inferior object for the first time a new
Python object is created. This object is then cached within GDB's
inferior object using the registry mechanism (see
inferior_to_inferior_object in py-inferior.c, specifically the calls
to inferior_data and set_inferior_data).
The Python Reference to the gdb.Inferior object held within the real
inferior object ensures that the reference count on the Python
gdb.Inferior object never reaches zero while the GDB inferior object
continues to exist.
At the same time, the gdb.Inferior object maintains a C++ pointer back
to GDB's real inferior object. We therefore end up with a system that
looks like this:
Python Reference
|
|
.----------. | .--------------.
| |------------------->| |
| inferior | | gdb.Inferior |
| |<-------------------| |
'----------' | '--------------'
|
|
C++ Pointer
When GDB's inferior object is deleted (say the inferior exits) then
py_free_inferior is called (thanks to the registry system), this
function looks up the Python gdb.Inferior object and sets the C++
pointer to nullptr and finally reduces the reference count on the
Python gdb.Inferior object.
If at this point the user still holds a reference to the Python
gdb.Inferior object then nothing happens. However, the gdb.Inferior
object is now in the non-valid state (see infpy_is_valid in
py-inferior.c), but otherwise, everything is fine.
However, if there are no further references to the Python gdb.Inferior
object, or, once the user has given up all their references to the
gdb.Inferior object, then infpy_dealloc is called.
This function currently checks to see if the inferior pointer within
the gdb.Inferior object is nullptr or not. If the pointer is nullptr
then infpy_dealloc immediately returns.
Only when the inferior point in the gdb.Inferior is not nullptr do
we (a) set the gdb.Inferior reference inside GDB's inferior to
nullptr, and (b) call the underlying Python tp_free function.
There are a number things wrong here:
1. The Python gdb.Inferior reference within GDB's inferior object
holds a reference count, thus, setting this reference to nullptr
without first decrementing the reference count would leak a
reference, however...
2. As GDB's inferior holds a reference then infpy_dealloc will never
be called until GDB's inferior object is deleted. Deleting a GDB
inferior ohject calls py_free_inferior, and so gives up the
reference. At this point there is no longer a need to call
set_inferior_data to set the field back to NULL, that field must
have been cleared in order to get the reference count to zero, which
means...
3. If we know that py_free_inferior must be called before
infpy_dealloc, then we know that the inferior pointer in
gdb.Inferior will always be nullptr when infpy_dealloc is called,
this means that the call to the underlying tp_free function will
always be skipped. Skipping this call will cause Python to leak the
memory associated with the gdb.Inferior object, which is what we
currently always do.
Given all of the above, I assert that the C++ pointer within
gdb.Inferior will always be nullptr when infpy_dealloc is called.
That's what this patch does.
I wrote a test for this issue making use of Pythons tracemalloc
module, which allows us to spot this memory leak.
Following 2 test points are failing with clang compiler
(gdb) FAIL: gdb.dwarf2/dw2-ref-missing-frame.exp: func_nofb print
(gdb) FAIL: gdb.dwarf2/dw2-ref-missing-frame.exp: func_loopfb print
As in commit f677852bbda "[gdb/testsuite] Use function_range in
gdb.dwarf2/dw2-abs-hi-pc.exp", the problem is that the CU and functions
have an empty address range, due to using asm labels in global scope,
which is a known source of problems, as explained in the comment of proc
function_range in gdb/testsuite/lib/dwarf.exp. Hence fix this also by
using function_range.
Tested on x86_64-linux with gcc and clang.
Add a new event, gdb.events.gdb_exiting, which is called once GDB
decides it is going to exit.
This event is not triggered in the case that GDB performs a hard
abort, for example, when handling an internal error and the user
decides to quit the debug session, or if GDB hits an unexpected,
fatal, signal.
This event is triggered if the user just types 'quit' at the command
prompt, or if GDB is run with '-batch' and has processed all of the
required commands.
The new event type is gdb.GdbExitingEvent, and it has a single
attribute exit_code, which is the value that GDB is about to exit
with.
The event is triggered before GDB starts dismantling any of its own
internal state, so, my expectation is that most Python calls should
work just fine at this point.
When considering this functionality I wondered about using the
'atexit' Python module. However, this is triggered when the Python
environment is shut down, which is done from a final cleanup. At
this point we don't know for sure what other GDB state has already
been cleaned up.
The test gdb.python/py-events.exp sets up a handler for the gdb.exited
event. Unfortunately the handler is slightly broken, it assumes that
the exit_code attribute will always be present. This is not always
the case.
In a later commit I am going to add more tests to py-events.exp test
script, and in so doing I expose the bug in our handling of gdb.exited
events.
Just to be clear, GDB itself is fine, it is the test that is not
written correctly according to the Python Events API.
So, in this commit I fix the Python code in the test, and extend the
test case to exercise more paths through the Python code.
Additionally, I noticed that the gdb.exited event is used as an
example in the documentation for how to write an event handler.
Unfortunately the same bug that we had in our test was also present in
the example code in the manual.
So I've fixed that too.
After this commit there is no functional change to GDB.
I noticed that some methods in language_defn could use
unique_xmalloc_ptr<char> rather than a plain 'char *'. This patch
implements this change, fixing up the fallout and changing
gdb_demangle to also return this type. In one spot, std::string is
used to simplify some related code, and in another, an auto_obstack is
used to avoid manual management.
Regression tested on x86-64 Fedora 34.
Say we use a gcc version that (while supporting c++11) does not support c++11
by default, and needs an -std setting to enable it.
If gdb would use the default AX_CXX_COMPILE_STDCXX from autoconf-archive, then
we'd have:
...
CXX="g++ -std=gnu++11"
...
That mechanism however has the following problem (quoting from commit
0bcda685399):
...
the top level Makefile passes CXX down to subdirs, and that overrides whatever
gdb/Makefile may set CXX to. The result would be that a make invocation from
the build/gdb/ directory would use "g++ -std=gnu++11" as expected, while a
make invocation at the top level would not.
...
Commit 0bcda685399 fixes this by using a custom AX_CXX_COMPILE_STDCXX which
does:
...
CXX=g++
CXX_DIALECT=-std=gnu++11
...
The problem reported in PR28318 is that using the custom instead of the
default AX_CXX_COMPILE_STDCXX makes the configure test for std::thread
support fail.
We could simply add $CXX_DIALECT to the test for std::thread support, but
that would have to be repeated for each added c++ support test.
Instead, fix this by doing:
...
CXX="g++ -std=gnu++11"
CXX_DIALECT=-std=gnu++11
...
This is somewhat awkward, since it results in -std=gnu++11 occuring twice in
some situations:
...
$ touch src/gdb/dwarf2/read.c
$ ( cd build/gdb; make V=1 dwarf2/read.o )
g++-4.8 -std=gnu++11 -x c++ -std=gnu++11 ...
...
However, both settings are needed:
- the switch in CXX for the std::thread tests (and other tests)
- the switch in CXX_DIALECT so it can be appended in Makefiles, to
counteract the fact that the top-level Makefile overrides CXX
The code added in gdb/ax_cxx_compile_stdcxx.m4 is copied from the default
AX_CXX_COMPILE_STDCXX from autoconf-archive.
Tested on x86_64-linux.
Bug: https://sourceware.org/bugzilla/show_bug.cgi?id=28318
Consider test-case gdb.trace/entry-values.exp with target board
unix/-fPIE/-pie.
Using this command we have an abbreviated version, and can see the correct
@entry values for foo:
...
$ gdb -q -batch outputs/gdb.trace/entry-values/entry-values \
-ex start \
-ex "break foo" \
-ex "set print entry-values both" \
-ex continue
Temporary breakpoint 1 at 0x679
Temporary breakpoint 1, 0x0000555555554679 in main ()
Breakpoint 2 at 0x55555555463e
Breakpoint 2, 0x000055555555463e in foo (i=0, i@entry=2, j=2, j@entry=3)
...
Now, let's try the same again, but run directly to foo rather than stopping at
main:
...
$ gdb -q -batch outputs/gdb.trace/entry-values/entry-values \
-ex "break foo" \
-ex "set print entry-values both" \
-ex run
Breakpoint 1 at 0x63e
Breakpoint 1, 0x000055555555463e in foo (i=0, i@entry=<optimized out>, \
j=2, j@entry=<optimized out>)
...
So, what explains the difference? Noteworthy, this is a dwarf assembly
test-case, with debug info for foo and bar, but not for main.
In the first case:
- we run to main
- this does not trigger expanding debug info, because there's none for main
- we set a breakpoint at foo
- this triggers expanding debug info. Relocated addresses are used in
call_site info (because the exec is started)
- we continue to foo, and manage to find the call_site info
In the second case:
- we set a breakpoint at foo
- this triggers expanding debug info. Unrelocated addresses are used in
call_site info (because the exec is not started)
- we run to foo
- this triggers objfile_relocate1, but it doesn't update the call_site
info addresses
- we don't manage to find the call_site info
We could fix this by adding the missing call_site relocation in
objfile_relocate1.
This solution however is counter-trend in the sense that we're trying to
work towards the situation where when starting two instances of an executable,
we need only one instance of debug information, implying the use of
unrelocated addresses.
So, fix this instead by using unrelocated addresses in call_site info.
Tested on x86_64-linux.
This fixes all remaining unix/-fno-PIE/-no-pie vs unix/-fPIE/-pie
regressions, like f.i. PR24892.
Bug: https://sourceware.org/bugzilla/show_bug.cgi?id=24892
Co-Authored-By: Tom de Vries <tdevries@suse.de>
In commit b4c919f7525 "[gdb/symtab] Fix htab_find_slot call in
read_call_site_scope" , I removed the comment:
...
It must be the first field as we overload core_addr_hash and core_addr_eq for
it.
...
for field pc of struct call_site.
However, this was not tested, and when indeed moving field pc to the second
location, we run into a testsuite failure in gdb.trace/entry-values.exp.
This is caused by core_addr_eq (the eq_f function for the htab) being
called with a pointer to the pc field (as passed into htab_find_slot) and a
pointer to a hash table element. Now that pc is no longer the first field,
the pointer to hash table element no longer points to the pc field.
This could be fixed by simply reinstating the comment, but we're trying to
get rid of this kind of tricks that make refactoring more difficult.
Instead, fix this by:
- reverting commit b4c919f7525, apart from the comment removal, such that
we're passing a pointer to element to htab_find_slot
- updating the htab_find_slot call in compunit_symtab::find_call_site
in a similar manner
- adding a call_site_eq and call_site_hash, and using these in the hash table
instead of core_addr_eq and core_addr_hash.
Tested on x86_64-linux, both with and without a trigger patch that moves pc to
the second location in struct call_site.
