This fixes some horrible code using do_scrub_chars. What we had ran
text through do_scrub_chars twice, directly in read_a_source_file and
again via the input_scrub_include_sb call. That's silly, and since
do_scrub_chars is a state machine, possibly wrong. More silliness is
evident in the temporary malloc'd buffer for do_scrub_chars output,
which should have been written directly to sbuf.
So, get rid of the do_scrub_chars call and support functions, leaving
scrubbing to input_scrub_include_sb. I did wonder about #NO_APP
overlapping input_scrub_next_buffer buffers, but that should only
happen if the string starts in one file and finishes in another.
* read.c (scrub_string, scrub_string_end): Delete.
(scrub_from_string): Delete.
(read_a_source_file): Rewrite #APP processing.
It is possible for sb_scrub_and_add_sb to not consume all of the input
string buffer. If this happens for reasons explained in the comment,
do_scrub_chars can leave pointers to the string buffer for the next
call. This patch fixes that by ensuring the input is drained. Note
that the behaviour for an empty string buffer is also changed,
avoiding another do_scrub_chars bug where empty input and single char
sized output buffers could result in a write past the end of the
output.
sb.c (sb_scrub_and_add_sb): Loop until all of input sb is
consumed.
Since commit b43771b045 it has been possible to look up addresses
that match a unit with errors, since ranges are added to a trie while
the unit is being parsed. On error, parse_comp_unit leaves
first_child_die_ptr NULL which results in a NULL info_ptr being passed
to scan_unit_for_symbols. Fix this by setting unit->error.
Also wrap some overlong lines, and fix some formatting errors.
* dwarf2.c: Formatting.
(parse_comp_unit): Set unit->error on err_exit path.
When running the selftests, I run into:
...
$ gdb -q -batch -ex "maint selftest"
...
Running selftest execute_cfa_program::aarch64:ilp32.
warning: A handler for the OS ABI "GNU/Linux" is not built into this
configuration of GDB. Attempting to continue with the default aarch64:ilp32
settings.
...
and likewise for execute_cfa_program::i8086 and
execute_cfa_program::ia64-elf32.
The warning can easily be reproduced outside the selftests by doing:
...
$ gdb -q -batch -ex "set arch aarch64:ilp32"
...
and can be prevented by first doing "set osabi none".
Fix the warning by setting osabi to none while doing selftests that iterate
over all architectures.
Tested on x86_64-linux.
This adds the gdb.current_language function, which can be used to find
the current language without (1) ever having the value "auto" or (2)
having to parse the output of "show language".
It also adds the gdb.Frame.language, which can be used to find the
language of a given frame. This is normally preferable if one has a
Frame object handy.
In an exception frame the PC register is extracted from the stack
just like other base registers, so there is no need for a special
treatment.
Signed-off-by: Torbjörn SVENSSON <torbjorn.svensson@st.com>
Signed-off-by: Yvan Roux <yvan.roux@foss.st.com>
The prologue unwinder had support for FPU registers, but only to
calculate the correct offset on the stack, the values were not saved.
Signed-off-by: Torbjörn SVENSSON <torbjorn.svensson@st.com>
Signed-off-by: Yvan Roux <yvan.roux@foss.st.com>
When unwinding the stack, the floating point registers d0 to d15
need to be handled as double words, not words.
Only the first 8 registers have been confirmed fixed with this patch
on a STM32F407-DISC0 board, but the upper 8 registers on Cortex-M33
should be handled in the same way.
The test consisted of running a program compiled with float-abi=hard.
In the main function, a function taking a double as an argument was
called. After the function call, a hardware timer was used to
trigger an interrupt.
In the debug session, a breakpoint was set in the function called
from main to verify the content of the registers using "info float"
and another breakpoint in the interrupt handler was used to check
the same registers using "info float" on frame 2 (the frame just
before the dummy frame created for the signal handler in gdb).
Signed-off-by: Torbjörn SVENSSON <torbjorn.svensson@st.com>
Signed-off-by: Yvan Roux <yvan.roux@foss.st.com>
Changed offset from decimal to hex to match architecture reference
manual terminology and keep coherency with the rest of the code.
Signed-off-by: Torbjörn SVENSSON <torbjorn.svensson@st.com>
Signed-off-by: Yvan Roux <yvan.roux@foss.st.com>
First, add three variables fpu_abi, fpu_hardfp and vdsp_version
to csky_gdbarch_tdep. They will be initialized from info.abfd in
cskg_gdbarch_init.
Now, they are just used to find a candidate among the list of pre-declared
architectures
Later, they will be used in gdbarch_return_value and gdbarch_push_dummy_call
for funtions described below:
fpu_abi: to check if the bfd is using VAL_CSKY_FPU_ABI_HARD or
VAL_CSKY_FPU_ABI_SOFT
fpu_hardfp: to check if the bfd is using VAL_CSKY_FPU_HARDFP_SINGLE
or VAL_CSKY_FPU_HARDFP_DOUBLE
vdsp_version: to check if a function is returned with CSKY_VRET_REGNUM
We can't use libiberty.a in chew. libiberty is a host library, chew
a build program. Partly revert commit 7273d78f3f, instead define
local versions of the libiberty functions. ansidecl.h also isn't
needed.
* doc/chew.c: Don't include libiberty.h or ansidecl.h.
(xmalloc, xrealloc, xstrdup): New functions.
* doc/local.mk (LIBIBERTY): Don't define or use.
* Makefile.in: Regenerate.
Update
commit 68c4956b14
Author: H.J. Lu <hjl.tools@gmail.com>
Date: Tue Apr 26 09:08:54 2022 -0700
x86: Properly handle function pointer reference
to properly handle IFUNC function pointer reference. Since IFUNC symbol
value is only known at run-time, set pointer_equality_needed for IFUNC
function pointer reference in PDE so that it will be resolved to its PLT
entry directly.
bfd/
PR ld/29216
* elf32-i386.c (elf_i386_scan_relocs): Set pointer_equality_needed
for IFUNC function pointer reference in PDE.
* elf64-x86-64.c (elf_x86_64_scan_relocs): Likewise.
ld/
PR ld/29216
* testsuite/ld-ifunc/ifunc.exp: Run PR ld/29216 test.
* testsuite/ld-ifunc/pr29216.c: New file.
A while back, I changed objfiles to be held via a shared_ptr. The
idea at the time was that this was a step toward writing to the index
cache in the background, and this would let gdb keep a reference alive
to do so. However, since then we've rewritten the DWARF reader, and
the new index can do this without requiring a shared pointer -- in
fact there are patches pending to implement this.
This patch switches objfile management to unique_ptr, which makes more
sense now.
Regression tested on x86-64 Fedora 34.
The order in which the variables in info common and info locals are
displayed is compiler (and dwarf) dependent. While all symbols should
be displayed the order is not fixed.
I added a gdb_test_multiple that lets ifx and ifort pass in cases where
only the order differs.
When value-printing a pointer within GDB by default GDB will look for
defined symbols residing at the address of the pointer. For the given
test the Intel/LLVM compiler stacks both display a symbol associated
with a printed pointer while the gnu stack does not. This leads to
failures in the test when running the test with CC_FOR_TARGET='clang'
CXX_FOR_TARGET='clang' F90_FOR_TARGET='flang'"
(gdb) b 37
(gdb) r
(gdb) f 6
(gdb) info args
a = 1
b = 2
c = 3
d = 4 + 5i
f = 0x419ed0 "abcdef"
g = 0x4041a0 <.BSS4>
or CC_FOR_TARGET='icx' CXX_FOR_TARGET='icpx' F90_FOR_TARGET='ifx'"
(gdb) b 37
(gdb) r
(gdb) f 6
(gdb) info args
a = 1
b = 2
c = 3
d = 4 + 5i
f = 0x52eee0 "abcdef"
g = 0x4ca210 <mixed_func_1a_$OBJ>
For the compiled binary the Intel/LLVM compilers both decide to move the
local variable g into the .bss section of their executable. The gnu
stack will keep the variable locally on the stack and not define a
symbol for it.
Since the behavior for Intel/LLVM is actually expected I adapted the
testcase at this point to be a bit more allowing for other outputs.
I added the optional "<SYMBOLNAME>" to the regex testing for g.
The given changes reduce the test fails for Intel/LLVM stack by 4 each.
While testing mixed-lang-stack I realized that valgrind actually
complained about a double free in the test.
All done
==2503051==
==2503051== HEAP SUMMARY:
==2503051== in use at exit: 0 bytes in 0 blocks
==2503051== total heap usage: 26 allocs, 27 frees, 87,343 bytes allocated
==2503051==
==2503051== All heap blocks were freed -- no leaks are possible
==2503051==
==2503051== For lists of detected and suppressed errors, rerun with: -s
==2503051== ERROR SUMMARY: 1 errors from 1 contexts (suppressed: 0 from 0)
Reason for this is that in mixed-lang-stack.cpp in mixed_func_1f an
object "derived_type obj" goes on the stack which is then passed-by-value
(so copied) to mixed_func_1g. The default copy-ctor will be called but,
since derived_type contains a heap allocated string and the copy
constructor is not implemented it will only be able to shallow copy the
object. Right after each of the functions the object gets freed - on the
other hand the d'tor of derived_type actually is implemented and calls
free on the heap allocated string which leads to a double free. Instead
of obeying the rule of 3/5 I just got rid of all that since it does not
serve the test. The string is now just a const char* = ".." object
member.
For ifort, ifx, and flang the tests "complete modm" and "complete
modmany" fail. This is because all three emit additional completion
suggestions. These additional suggestions have their origin in symbols
emitted by the compilers which can also be completed from the respective
incomplete word (modm or modmany). For this specific example gfortran
does not emit any additional symbols.
For example, in this test the linkage name for var_a in ifx is
"modmany_mp_var_a_" while gfortran uses "__modmany_MOD_var_a" instead.
Since modmany_mp_var_a can be completed from modm and also modmany they
will get displayed, while gfortran's symbol starts with "__" and thus will
be ignored (it cannot be a completion of a word starting with "m").
Similar things happen in flang and ifort. Some example output is shown
below:
FLANG
(gdb) complete p modm
p modmany
p modmany::var_a
p modmany::var_b
p modmany::var_c
p modmany::var_i
p modmany_
IFX/IFORT
(gdb) complete p modm
p modmany
p modmany._
p modmany::var_a
p modmany::var_b
p modmany::var_c
p modmany::var_i
p modmany_mp_var_a_
p modmany_mp_var_b_
p modmany_mp_var_c_
p modmany_mp_var_i_
GFORTRAN
(gdb) complete p modm
p modmany
p modmany::var_a
p modmany::var_b
p modmany::var_c
p modmany::var_i
I want to emphasize: for Fortran (and also C/C++) the complete command
does not actually check whether its suggestions make sense - all it does
is look for any symbol (in the minimal symbols, partial symbols etc.)
that a given substring can be completed to (meaning that the given substring
is the beginning of the symbol). One can easily produce a similar
output for the gfortran compiled executable. For this look at the
slightly modified "complete p mod" in gfortran:
(gdb) complete p mod
p mod1
p mod1::var_const
...
p mod_1.c
p modcounter
p mode_t
p modf
...
p modify_ldt
p modmany
p modmany::var_a
p modmany::var_b
p modmany::var_c
p modmany::var_i
p module
p module.f90
p module_entry
p moduse
p moduse::var_x
p moduse::var_y
Many of the displayed symbols do not actually work with print:
(gdb) p mode_t
Attempt to use a type name as an expression
(gdb) p mod_1.c
No symbol "mod_1" in current context.
(gdb)
I think that in the given test the output for gfortran only looks nice
"by chance" rather than is actually expected. Expected is any output
that also contains the completions
p modmany
p modmany::var_a
p modmany::var_b
p modmany::var_c
p modmany::var_i
while anythings else can be displayed as well (depending on the
compiler and its emitted symbols).
This, I'd consider all three outputs as valid and expected - one is just
somewhat lucky that gfortran does not produce any additional symbols that
got matched.
The given patch improves test performance for all three compilers
by allowing additional suggested completions inbetween and after
the two given blocks in the test. I did not allow additional print
within the modmany_list block since the output is ordered alphabetically
and there should normally not appear any additional symbols there.
For flang/ifx/ifort I each see 2 failures less (which are exactly the two
complete tests).
As a side note and since I mentioned C++ in the beginning: I also tried
the gdb.cp/completion.exp. The output seems a bit more reasonable,
mainly since C++ actually has a demangler in place and linkage symbols
do not appear in the output of complete. Still, with a poor enough
to-be-completed string one can easily produce similar results:
(gdb) complete p t
...
p typeinfo name for void
p typeinfo name for void const*
p typeinfo name for void*
p typeinfo name for wchar_t
p typeinfo name for wchar_t const*
p typeinfo name for wchar_t*
p t *** List may be truncated, max-completions reached. ***
(gdb) p typeinfo name for void*
No symbol "typeinfo" in current context.
(gdb) complete p B
p BACK_SLASH
p BUF_FIRST
p BUF_LAST
...
p Base
p Base::Base()
p Base::get_foo()
p bad_key_err
p buf
p buffer
p buffer_size
p buflen
p bufsize
p build_charclass.isra
(gdb) p bad_key_err
No symbol "bad_key_err" in current context.
(compiled with gcc/g++ and breaking at main).
This patch is only about making the referenced test more 'fair' for the
other compilers. Generally, I find the behavior of complete a bit
confusing and maybe one wants to change this at some point but this
would be a bigger task.
This info-types.exp test case had a few issues that this patch fixes.
First, the emitted symbol character(kind=1)/character*1 (different
compilers use different naming converntions here) which is checkedin the
test is not actually expected given the test program. There is no
variable of that type in the test. Still, gfortran emits it for every
Fortran program there is. The reason is the way gfortran handles Fortran's
named main program. It generates a wrapper around the Fortran program
that is quite similar to a C main function. This C-like wrapper has
argc and argv arguments for command line argument passing and the argv
pointer type has a base type character(kind=1) DIE emitted at CU scope.
Given the program
program prog
end program prog
the degbug info gfortran emits looks somewhat like
<0><c>: Abbrev Number: 3 (DW_TAG_compile_unit)
...
<1><2f>: Abbrev Number: 4 (DW_TAG_subprogram)
<30> DW_AT_external : 1
<30> DW_AT_name : (indirect string, ...): main
...
<2><51>: Abbrev Number: 1 (DW_TAG_formal_parameter)
<52> DW_AT_name : (indirect string, ...): argc
...
<2><5d>: Abbrev Number: 1 (DW_TAG_formal_parameter)
<5e> DW_AT_name : (indirect string, ...): argv
...
<62> DW_AT_type : <0x77>
...
<2><6a>: Abbrev Number: 0
...
<1><77>: Abbrev Number: 6 (DW_TAG_pointer_type)
<78> DW_AT_byte_size : 8
<79> DW_AT_type : <0x7d>
<1><7d>: Abbrev Number: 2 (DW_TAG_base_type)
<7e> DW_AT_byte_size : 1
<7f> DW_AT_encoding : 8 (unsigned char)
<80> DW_AT_name : (indirect string, ...): character(kind=1)
<1><84>: Abbrev Number: 7 (DW_TAG_subprogram)
<85> DW_AT_name : (indirect string, ...): prog
...
Ifx and flang do not emit any debug info for a wrapper main method so
the type is missing here. There was the possibility of actually adding
a character*1 type variable to the Fortran executable, but both, ifx and
gfortran chose to emit this variable's type as a DW_TAG_string_type of
length one (instead of a character(kind=1), or whatever the respective
compiler naming convention is). While string types are printed as
character*LENGHT in the fortran language part (e.g. when issuing a
'ptype') they do not generate any symbols inside GDB. In read.c it says
/* These dies have a type, but processing them does not create
a symbol or recurse to process the children. Therefore we can
read them on-demand through read_type_die. */
So they did not add any output to 'info types'. Only flang did emit a
character type here.
As adding a type would have a) not solved the problem for ifx and would
have b) somehow hidden the curious behavior of gfortran, instead, the
check for this character type was chagened to optional with the
check_optional_entry to allow for the symbols's absence and to allow
flang and ifx to pass this test as well.
Second, the line checked for s1 was hardcoded as 37 in the test. Given
that the type is actually defined on line 41 (which is what is emitted by
ifx) it even seems wrong. The line check for s1 was changed to actually
check for 41 and a gfortran bug has been filed here
https://gcc.gnu.org/bugzilla/show_bug.cgi?id=105454
The test is now marked as xfail for gfortran.
Third, the whole test of checking for the 'Type s1' in info types seemed
questionable. The type s1 is declared iside the scope of the Fortran
program info_types_test. Its DIE however is emitted as a child of the
whole compilation unit making it visible outside of the program's scope.
The 'info types' command checks for types stored in the GLOBAL_BLOCK,
or STATIC_BLOCKm wgucm according to block.h
The GLOBAL_BLOCK contains all the symbols defined in this compilation
whose scope is the entire program linked together.
The STATIC_BLOCK contains all the symbols whose scope is the
entire compilation excluding other separate compilations.
so for gfortran, the type shows up in the output of 'info types'. For
flang and ifx on the other hand this is not the case. The two compilers
emit the type (correctly) as a child of the Fortran program, thus not
adding it to either, the GLOBAL_BLOCK nor the LOCAL_BLOCK. A bug has
been opened for the gfortran scoping issue:
https://gcc.gnu.org/bugzilla/show_bug.cgi?id=105454
While the most correct change might have been removing the check for s1,
the change made here was to only check for this type in case of gfortran
being used as the compiler, as this check also covers the declaration
line issue mentioned above. A comment was added to maybe remove this
check once the scoping issue is resolved (and it starts to fail with
newer gfortran versions). The one used to test these changes was 13.0.
There was already a similar functionality for the GDBInfoModuleSymbols.
This just extends the GDBInfoSymbols. We will use this feature in a
later commit to make a testcase less GNU specific and more flexible for
other compilers.
Namely, in gdb.fortran/info-types.exp currenlty
GDBInfoSymbols::check_entry is used to verify and test the output of the
info symbols command. The test, however was written with gfortran as a
basis and some of the tests are not fair with e.g. ifx and ifort as
they test for symbols that are not actually required to be emitted. The
lines
GDBInfoSymbols::check_entry "${srcfile}" "" "${character1}"
and
GDBInfoSymbols::check_entry "${srcfile}" "37" "Type s1;"
check for types that are either not used in the source file (character1)
or should not be emitted by the compiler at global scope (s1) thus no
appearing in the info symbols command. In order to fix this we will
later use the newly introduced check_optional_entry over check_entry.
In order for ifx and ifort to emit all debug entries, even for unused
parameters in modules we have to define the '-debug-parameters all' flag.
This commit adds it to the ifx-*/ifort-* specific flags in gdb.exp.
The test was earlier not using the compiler dependent type print system
in fortran.exp. I changed this. It should generally improve the test
performance for different compilers. For ifx and gfortran I do not see
any failures.
Currenlty, ifx/ifort cannot compile the given executable as it is not
valid Fortran. It is missing the external keyword on the
no_arg_subroutine. Gfortran compiles the example but this is actually
a bug and there is an open gcc ticket for this here:
https://gcc.gnu.org/bugzilla/show_bug.cgi?id=50377
Adding the keyword does not change the gfortran compiling of the example.
It will, however, prevent a future fail once 50377 has been addressed.
The test specifically tests for the Fortran CHARACTER(KIND=4) which is
not available in ifx/ifort.
Since the other characters are also printed elsewhere, we disable this
test for the unsupported compilers.
The name for icx and icpx in the testsuite was earlier set to 'intel-*'
by the compiler identification. This commit changes this to 'icx-*'.
Note, that currently these names are not used within the testsuite so no
tests have to be adapted here.
This commit adds a separate Fortran compiler identification mechanism to
the testsuite, similar to the existing one for C/C++. Before this
change, the options and version for the Fortran compiler specified when
running the testsuite with F90_FOR_TARGET set, was detected via its
respective C compiler. So running the testsuite as
make check TEST=gdb.fortran/*.exp CC_FOR_TARGET=gcc F90_FOR_TARGET=ifx
or even
make check TEST=gdb.fortran/*.exp F90_FOR_TARGET=ifx
would use the gcc compiler inside the procedures get_compiler_info and
test_compiler_info to identify compiler flags and the compiler version.
This could sometimes lead to unpredictable outputs. It also limited
testsuite execution to combinations where C and Fortran compiler would
come from the same family of compiers (gcc/gfortran, icc/ifort, icx/ifx,
clang/flang ..). This commit enables GDB to detect C and Fortran
compilers independently of each other.
As most/nearly all Fortran compilers have a mechanism for preprocessing
files in a C like fashion we added the exact same meachnism that already
existed for C/CXX. We let GDB preprocess a file with the compilers
Fortran preprocessor and evaluate the preprocessor defined macros in that
file.
This enables GDB to properly run heterogeneous combinations of C and
Fortran compilers such as
CC_FOR_TARGET='gcc' and F90_FOR_TARGET='ifort'
or enables one to run the testsuite without specifying a C compiler as in
make check TESTS=gdb.fortran/*.exp F90_FOR_TARGET='ifx'
make check TESTS=gdb.fortran/*.exp F90_FOR_TARGET='flang'
On the other hand this also requires one to always specify a
identification mechanism for Fortran compilers in the compiler.F90 file.
We added identification for GFORTRAN, FLANG (CLASSIC and LLVM) IFX,
IFORT, and ARMFLANG for now.
Classic and LLVM flang were each tested with their latest releases on
their respective release pages. Both get recognized by the new compiler
identification and we introduced the two names flang-classic and
flang-llvm to distinguish the two. While LLVM flang is not quite mature
enough yet for running the testsuite we still thought it would be a good
idea to include it already. For this we added a case for the fortran_main
procedure. LLVM flang uses 'MAIN__' as opposed to classic flang which
uses 'MAIN_' here.
We did not have the possibility to test ARMFLANG - the versioning scheme
here was extracted from its latest online documentation.
We changed the test_compiler_info procedure to take another optional
argument, the language string, which will be passed though to the
get_compiler_info procedure. Passing 'f90' or 'c++' here will then
trigger the C++/Fortran compiler identification within
get_compiler_info. The latter procedure was extended to also handle
the 'f90' argument (similarly to the already existing 'c++' one).
Co-authored-by: Nils-Christian Kempke <nils-christian.kempke@intel.com>
The procedure gdb_compile queries its options via
[lsearch -exact $options getting_compiler_info]
to check whether or not it was called in with the option
getting_compiler_info. If it was called with this option it would
preprocess some test input to try and figure out the actual compiler
version of the compiler used. While doing this we cannot again try to
figure out the current compiler version via the 'getting_compiler_info'
option as this would cause infinite recursion. As some parts of the
procedure do recursively test for the compiler version to e.g. set
certain flags, at several places gdb_compile there are checks for the
getting_compiler_info option needed.
In the procedure, there was already a variable 'getting_compiler_info'
which was set to the result of the 'lsearch' query and used instead of
again and again looking for getting_compiler_info in the procedure
options. But, this variable was actually set too late within the code.
This lead to a mixture of querying 'getting_compiler_info' or
doing an lserach on the options passed to the procedure.
I found this inconsistent and instead moved the variable
getting_compiler_info to the front of the procedure. It is set to true
or false depending on whether or not the argument is found in the
procedure's options (just as before) and queried instead of doing an
lsearch on the procedure options in the rest of the procedure.
Newer Intel compilers emit their dwarf type name in a slightly different
format. Therefore, this needs adjustment to make more tests pass in the
Fortran testsuite.
Co-authored-by: Abdul Basit Ijaz <abdul.b.ijaz@intel.com>
Co-authored-by: Nils-Christian Kempke <nils-christian.kempke@intel.com>
The last uses of the F77_FOR_TARGET via passing f77 to GDB's compile
procedure were removed in this commit
commit 0ecee54cfd
Author: Tom Tromey <tromey@redhat.com>
Date: Wed Jun 29 17:50:47 2011 +0000
over 10 years ago. The last .f files in the testsuite by now are all
being compiled by passing 'f90' to the GDB compile, thus only actually
using F90_FOR_TARGET (array-element.f, block-data.f, subarray.f).
Gfortran in this case is backwards compatible with most f77 code as
claimed on gcc.gnu.org/fortran.
The reason we'd like to get rid of this now is, that we'll be
implementing a Fortran compiler identification mechanism, similar to the
C/Cpp existing ones. It would be using the Fortran preprocessor macro
defines to identify the Fortran compiler version at hand. We found it
inconsequent to only implement this for f90 but, on the other hand, f77
seems deprecated. So, with this commit we remove the remaining lines for
its support.
In the name matching unit tests in gdb/dwarf2/read.c, explain better
why we test symbols with \377 / 0xff characters (Latin1 'ÿ').
Change-Id: I517f13adfff2e4d3cd783fec1d744e2b26e18b8e
SYMBOL_REFERENCES_LOCAL can return true for undefined symbols. This
can result in a segfault when running sparc64 ld/testsuite/ld-vsb
tests that expect a failure.
* elfxx-sparc.c (_bfd_sparc_elf_finish_dynamic_symbol): Don't
access u.def.section on non-default visibility undefined symbol.
v850_elf_set_note is declared using an unsigned int note param in
elf32-v850.h but defined with enum c850_notes note in elf32-v850.c.
Current mainline gcc is warning about this. Huh.
* elf32-v850.c (v850_elf_set_note): Make "note" param an
unsigned int.
git commit 202be274a4 also missed adjusting a few testsuite files.
This fixes
i686-vxworks +FAIL: VxWorks shared library test 1
i686-vxworks +FAIL: VxWorks executable test 1 (dynamic)
git commit 202be274a4 went a little wild in removing trailing spaces
in gas/testsuite/gas/i386/{secidx.d,secrel.d}, causing
x86_64-w64-mingw32 +FAIL: i386 secrel reloc
x86_64-w64-mingw32 +FAIL: i386 secidx reloc
I could have just replaced the trailing space, but let's fix the
objdump output instead. Touches lots of testsuite files.
Patch
202be274a4 ("opcodes/i386: remove trailing whitespace from insns with zero operands")
causes this regression:
FAIL: gdb.trace/signal.exp: find syscall insn in kill
It's because the test still expects to match a whitespace after the
instruction, which the patch mentioned above removed. Remove the
whitespaces for the regexp.
Change-Id: Ie194273cc942bfd91332d4035f6eec55b7d3a428
The current "Specify Location" section of the GDB manual starts with:
"Several @value{GDBN} commands accept arguments that specify a location
of your program's code."
And then, such commands are documented as taking a "location"
argument. For example, here's a representative subset:
@item break @var{location}
@item clear @var{location}
@item until @var{location}
@item list @var{location}
@item edit @var{location}
@itemx info line @var{location}
@item info macros @var{location}
@item trace @var{location}
@item info scope @var{location}
@item maint agent @r{[}-at @var{location}@r{,}@r{]} @var{expression}
The issue here is that "location" isn't really correct for most of
these commands. Instead, the "location" argument is really a
placeholder that represent an umbrella term for all of the
"linespecs", "explicit location", and "address location" input
formats. GDB parses these and then finds the actual code locations
(plural) in the program that match. For example, a "location"
specified like "-function func" will actually match all the code
locations in the program that correspond to the address/file/lineno of
all the functions named "func" in all the loaded programs and shared
libraries of all the inferiors. A location specified like "-function
func -label lab" matches all the addresses of C labels named "lab" in
all functions named "func". Etc.
This means that several of the commands that claim they accept a
"location", actually end up working with multiple locations, and the
manual doesn't explain that all that well. In some cases, the command
will work with all the resolved locations. In other cases, the
command aborts with an error if the location specification resolves to
multiple locations in the program. In other cases, GDB just
arbitrarily and silently picks whatever is the first resolved code
location (which sounds like should be improved).
To clarify this, I propose we use the term "Location Specification",
with shorthand "locaction spec", when we're talking about the user
input, the argument or arguments that is/are passed to commands to
instruct GDB how to find locations of interest. This is distinct from
the actual code locations in the program, which are what GDB finds
based on the user-specified location spec. Then use "location
specification or the shorter "location spec" thoughout instead of
"location" when we're talking about the user input.
Thus, this commit does the following:
- renames the "Specify Location" section of the manual to "Location
Specifications".
- It then introduces the term "Location Specification", with
corresponding shorthand "location spec", as something distinct from
an actual code location in the program. It explains what a concrete
code location is. It explains that a location specification may be
incomplete, and that may match multiple code locations in the
program, or no code location at all. It gives examples. Some
pre-existing examples were moved from the "Set Breaks" section, and
a few new ones that didn't exist yet were added. I think it is
better to have these centralized in this "Location Specification"
section, since all the other commands that accept a location spec
have an xref that points there.
- Goes through the manual, and where "@var{location}" was used for a
command argument, updated it to say "@var{locspec}" instead. At the
same time, tweaks the description of the affected commands to
describe what happens when the location spec resolves to more than
one location. Most commands just did not say anything about that.
One command -- "maint agent -at @var{location}" -- currently says it
accepts a "location", suggesting it can accept address and explicit
locations too, but that's incorrect. In reality, it only accepts
linespecs, so fix it accordingly.
One MI command -- "-trace-find line" -- currently says it accepts a
"line specification", but it can accept address and explicit
locations too, so fix it accordingly.
Special thanks goes to Eli Zaretskii for reviews and rewording
suggestions.
Change-Id: Ic42ad8565e79ca67bfebb22cbb4794ea816fd08b
Doing a 32-bit build with "--enable-targets=all --disable-sim" fails to link
properly.
--
loongarch-tdep.o: In function `loongarch_gdbarch_init':
binutils-gdb/gdb/loongarch-tdep.c:443: undefined reference to `loongarch_r_normal_name'
loongarch-tdep.o: In function `loongarch_fetch_instruction':
binutils-gdb/gdb/loongarch-tdep.c:37: undefined reference to `loongarch_insn_length'
loongarch-tdep.o: In function `loongarch_scan_prologue(gdbarch*, unsigned long long, unsigned long long, frame_info*, trad_frame_cache*) [clone .isra.4]':
binutils-gdb/gdb/loongarch-tdep.c:87: undefined reference to `loongarch_insn_length'
binutils-gdb/gdb/loongarch-tdep.c:88: undefined reference to `loongarch_decode_imm'
binutils-gdb/gdb/loongarch-tdep.c:89: undefined reference to `loongarch_decode_imm'
binutils-gdb/gdb/loongarch-tdep.c:90: undefined reference to `loongarch_decode_imm'
binutils-gdb/gdb/loongarch-tdep.c:91: undefined reference to `loongarch_decode_imm'
binutils-gdb/gdb/loongarch-tdep.c:92: undefined reference to `loongarch_decode_imm'
--
Given the list of 64-bit BFD files in
opcodes/Makefile.am:TARGET64_LIBOPCODES_CFILES, it looks like GDB's
ALL_TARGET_OBS list is including files that should be included in
ALL_64_TARGET_OBS instead.
This patch accomplishes this and enables a 32-bit build with
"--enable-targets=all --disable-sim" to complete.
Moving the bpf, tilegx and loongarch files to the correct list means GDB can
find the correct disassembler function instead of finding a null pointer.
We still need the "--disable-sim" switch (or "--enable-64-bit-bfd") to
make a 32-bit build with "--enable-targets=all" complete correctly
