Just like their packed counterparts the memory operand is always 16
bytes wide, and the Disp8 scaling is the same for all of them. (As a
side note: I'm also surprised by there being AVX512VL variants of
these as well as the AVX512_4VNNIW ones - the SDM doesn't define any
such.)
Adjust the test cases also for the packed forms to actually live up to
their promise of testing correct Disp8 encoding.
gas/
* testsuite/gas/riscv/auipc-x0.d: New.
* testsuite/gas/riscv/auipc-x0.s: New.
opcodes/
* riscv-dis.c (maybe_print_address): If base_reg is zero,
then the hi_addr value is zero.
Since the 'info proc' support on FreeBSD does not use /proc, reword
the documentation for 'info proc' to not assume /proc. This includes
renaming the node to 'Process Information' and suggesting that
additional process information can be queried via different
OS-specific interfaces. This is also cleans up the description of
'info proc' support for core files a bit as /proc is not used for core
file support on any current platform.
gdb/ChangeLog:
* NEWS: Document that 'info proc' now works on FreeBSD.
gdb/doc/ChangeLog:
* gdb.texinfo (pwd): Update cross-reference for Process Information
node and remove explicit /proc reference.
(Native): Rename subsection from SVR4 Process Information to
Process Information.
(Process Information): Reword introduction to be less /proc
centric. Document support for "info proc" on FreeBSD.
- Command line arguments are fetched via the kern.proc.args.<pid>
sysctl.
- The 'cwd' and 'exe' values are obtained from the per-process
file descriptor table returned by kinfo_getfile() from libutil.
- 'mappings' is implemented by walking the array of VM map entries
returned by kinfo_getvmmap() from libutil.
- 'status' output is generated by outputting fields from the structure
returned by the kern.proc.pid.<pid> sysctl.
- 'stat' is aliased to 'status'.
gdb/ChangeLog:
* configure.ac: Check for kinfo_getfile in libutil.
* configure: Regenerate.
* config.in: Regenerate.
* fbsd-nat.c: Include "fbsd-tdep.h".
(fbsd_fetch_cmdline): New.
(fbsd_fetch_kinfo_proc): Move earlier and change to return a bool
rather than calling error.
(fbsd_info_proc): New.
(fbsd_thread_name): Report error if fbsd_fetch_kinfo_proc fails.
(fbsd_wait): Report warning if fbsd_fetch_kinfo_proc fails.
(fbsd_nat_add_target): Set "to_info_proc" to "fbsd_info_proc".
Since xfree() always wraps free(), it is safe to use the xfree deleter
for buffers allocated by library routines such as kinfo_getvmmap() that
must be released via free().
gdb/ChangeLog:
* fbsd-nat.c (struct free_deleter): Remove.
(fbsd_find_memory_regions): Use gdb::unique_xmalloc_ptr<>.
For processes without an associated executable (such as kernel processes),
the kern.proc.pathname.<pid> system control node returns a length of zero
without modifying the user's buffer. Detect this case and return NULL
rather than the previous contents of the static buffer 'buf'.
gdb/ChangeLog:
* fbsd-nat.c (fbsd_pid_to_exec_file) [KERN_PROC_PATHNAME]: Return
NULL for an empty pathname.
- Command line arguments are obtained from the pr_psargs[] array
saved in the NT_PRPSINFO note.
- The 'cwd' and 'exe' values are obtained from the per-process file
descriptor table stored in the NT_PROCSTAT_FILES core note.
- 'mappings' is implemented by walking the array of VM map entries
stored in the NT_PROCSTAT_VMMAP core note.
- 'status' output is generated by outputting fields from
the first structure stored in the NT_PROCSTAT_PROC core note.
- 'stat' is aliased to 'status'.
gdb/ChangeLog:
* fbsd-tdep.c (KVE_STRUCTSIZE, KVE_START, KVE_END, KVE_OFFSET)
(KVE_FLAGS, KVE_PROTECTION, KVE_PATH, KINFO_VME_PROT_READ)
(KINFO_VME_PROT_WRITE, KINFO_VME_PROT_EXEC, KINFO_VME_FLAG_COW)
(KINFO_VME_FLAG_NEEDS_COPY, KINFO_VME_FLAG_NOCOREDUMP)
(KINFO_VME_FLAG_SUPER, KINFO_VME_FLAG_GROWS_UP)
(KINFO_VME_FLAG_GROWS_DOWN, KF_STRUCTSIZE, KF_TYPE, KF_FD)
(KF_PATH, KINFO_FILE_TYPE_VNODE, KINFO_FILE_FD_TYPE_CWD)
(KINFO_FILE_FD_TYPE_TEXT, SIG_WORDS, struct kinfo_proc_layout)
(kinfo_proc_layout_32, kinfo_proc_layout_i386)
(kinfo_proc_layout_64, fbsd_vm_map_entry_flags)
(fbsd_core_info_proc_mappings, fbsd_core_vnode_path)
(fbsd_core_fetch_timeval, fbsd_print_sigset)
(fbsd_core_info_proc_status, fbsd_core_info_proc): New.
(fbsd_init_abi): Install gdbarch "core_info_proc" method.
* fbsd-tdep.h (fbsd_vm_map_entry_flags): New.
CSDB is a new instruction which Arm has defined. As it shares the
encoding space with NOP instructions, it is available from Armv3 in
Arm mode, and Armv6T2 in Thumb mode.
OK? If so, please commit on my behalf as I don't have commit rights
over here.
Thanks, James
---
opcodes/
2018-01-09 James Greenhalgh <james.greenhalgh@arm.com>
* arm-dis.c (arm_opcodes): Add csdb.
(thumb32_opcodes): Add csdb.
gas/
2018-01-09 James Greenhalgh <james.greenhalgh@arm.com>
* config/tc-arm.c (insns): Add csdb, enable for Armv3 and above
in Arm execution state, and Armv6T2 and above in Thumb execution
state.
* testsuite/gas/arm/csdb.s: New.
* testsuite/gas/arm/csdb.d: New.
* testsuite/gas/arm/thumb2_it_bad.l: Add csdb.
* testsuite/gas/arm/thumb2_it_bad.s: Add csdb.
CSDB is a new instruction which Arm has defined. It has the same encoding as
HINT #0x14 and is available at all architecture levels.
opcodes * aarch64-tbl.h (aarch64_opcode_table): Add "csdb".
* aarch64-asm-2.c: Regenerate.
* aarch64-dis-2.c: Regenerate.
* aarch64-opc-2.c: Regenerate.
gas * testsuite/gas/aarch64/system.d: Update expected results to expect
CSDB.
Using this Ada example:
package B is
procedure Read_Small with Inline_Always;
end B;
package body B is
Total : Natural := 0;
procedure Read_Small is
begin
Total := Total + 1;
end Read_Small;
end B;
and
with B;
procedure M is
begin
B.Read_Small;
end M;
% gnatmake -g -O0 -m m.adb -cargs -gnatn
% gdb m
Inserting a breakpoint on Read_Small inlined function does not work:
(gdb) b read_small
Breakpoint 1 at 0x40250e: file b.adb, line 5.
(gdb) info b
Num Type Disp Enb Address What
1 breakpoint keep y 0x000000000040250e in b.doit at b.adb:5
(gdb)
In this exemple we should have two breakpoints set, one in package B and
the other one in the inlined instance inside procedure M), like below:
(gdb) b read_small
Breakpoint 1 at 0x40250e: b.adb:5. (2 locations)
(gdb) info b
Num Type Disp Enb Address What
1 breakpoint keep y <MULTIPLE>
1.1 y 0x000000000040250e in b.doit at b.adb:5
1.2 y 0x0000000000402540 in m at b.adb:5
(gdb)
Looking at the DWARF info for inlined instance of Read_Small:
<1><1526>: Abbrev Number: 2 (DW_TAG_subprogram)
<1527> DW_AT_name : ([...], offset: 0x1e82): b__read_small
<152b> DW_AT_decl_file : 2
<152c> DW_AT_decl_line : 3
<152d> DW_AT_inline : 3 (declared as inline and inlined)
[...]
<2><1547>: Abbrev Number: 4 (DW_TAG_inlined_subroutine)
<1548> DW_AT_abstract_origin: <0x1526>
<154c> DW_AT_low_pc : 0x402552
<1554> DW_AT_high_pc : 0x2b
<155c> DW_AT_call_file : 1
<155d> DW_AT_call_line : 5
<2><155e>: Abbrev Number: 0
During the parsing of DWARF info in order to produce partial DIE linked
list, the DW_TAG_inlined_subroutine were skipped thus not present in the
final partial dies.
Taking DW_TAG_inlined_subroutine in account during the parsing process
fixes the problem.
gdb/ChangeLog:
* dwarf2read.c (scan_partial_symbols, add_partial_symbol)
(add_partial_subprogram, load_partial_dies): Add
DW_TAG_inlined_subroutine handling.
gdb/testsuite/ChangeLog:
* gdb.ada/bp_inlined_func: New testcase.
Add PIE support for hurd, by faking an AT_ENTRY auxv entry. That value
is expected to be read by svr4_exec_displacement, which will propagate
the executable displacement.
gdb/ChangeLog:
* gdb/gnu-nat.c: Include <elf.h> and <link.h>.
(gnu_xfer_auxv): New function.
(gnu_xfer_partial): Call gnu_xfer_auxv when `object' is
TARGET_OBJECT_AUXV.
For historical reason, we allow movd/vmovd with 64-bit register and
memeory operands. But for vmovd, we failed to handle 64-bit memeory
operand. This has been gone unnoticed since AT&T syntax always treats
memory operand as 32-bit memory. This patch properly encodes vmovd
with 64-bit memeory operands. It also removes AVX512 vmovd with 64-bit
operands since GCC has
case TYPE_SSEMOV:
switch (get_attr_mode (insn))
{
case MODE_DI:
/* Handle broken assemblers that require movd instead of movq. */
if (!HAVE_AS_IX86_INTERUNIT_MOVQ
&& (GENERAL_REG_P (operands[0]) || GENERAL_REG_P (operands[1])))
return "%vmovd\t{%1, %0|%0, %1}";
return "%vmovq\t{%1, %0|%0, %1}";
and all AVX512 GNU assemblers set HAVE_AS_IX86_INTERUNIT_MOVQ, GCC won't
generate AVX512 vmovd with 64-bit operand.
gas/
PR gas/22681
* testsuite/gas/i386/i386.exp: Run x86-64-movd and
x86-64-movd-intel.
* testsuite/gas/i386/x86-64-movd-intel.d: New file.
* testsuite/gas/i386/x86-64-movd.d: Likewise.
* testsuite/gas/i386/x86-64-movd.s: Likewise.
opcodes/
PR gas/22681
* i386-opc.tbl: Properly encode vmovd with Qword memeory operand.
Remove AVX512 vmovd with 64-bit operands.
* i386-tbl.h: Regenerated.
When we set bfd/development.sh:$development to false, GDBserver failed to
build,
selftest.o: In function `selftests::run_tests(char const*)':
binutils-gdb/gdb/gdbserver/../common/selftest.c:97:undefined reference to `selftests::reset()'
collect2: error: ld returned 1 exit status
selftest.o shouldn't be compiled and linked when $development is false.
With this patch, in release mode, GDBserver doesn't nothing with option
--selftest,
$ ./gdbserver --selftest=foo
Selftests are not available in a non-development build.
$ ./gdbserver --selftest
Selftests are not available in a non-development build.
gdb/gdbserver:
2018-01-08 Yao Qi <yao.qi@linaro.org>
Simon Marchi <simon.marchi@ericsson.com>
* Makefile.in (OBS): Remove selftest.o.
* configure.ac: Set srv_selftest_objs if $development is true.
(GDBSERVER_DEPFILES): Append $srv_selftest_objs.
* configure: Re-generated.
* server.c (captured_main): Wrap variable selftest_filter with
GDB_SELF_TEST.
gdb/testsuite:
2018-01-08 Simon Marchi <simon.marchi@ericsson.com>
* gdb.server/unittest.exp: Match the output in non-development
mode.
We don't build GDB selftests bits when $development is false. However, if
we turn bfd/development.sh:$development to false, common/selftest.c is
compiled which is not expected. It causes the build failure,
selftest.o: In function `selftests::run_tests(char const*)':
binutils-gdb/gdb/common/selftest.c:97: undefined reference to `selftests::reset()'
collect2: error: ld returned 1 exit status
I fix this issue by putting selftest.o selftest-arch.o into CONFIG_OBS
only when $development is true. After this is fixed, there are other
build failures in maint.c, this patch fixes them as well.
In the release mode, the output of these commands are:
(gdb) maintenance selftest
Selftests are not available in a non-development build.
(gdb) maintenance selftest foo
Selftests are not available in a non-development build.
(gdb) maintenance info selftests
Selftests are not available in a non-development build.
gdb:
2018-01-08 Yao Qi <yao.qi@linaro.org>
Simon Marchi <simon.marchi@ericsson.com>
* Makefile.in (COMMON_SFILES): Remove selftest-arch.c and
common/selftest.c.
(COMMON_OBS): Remove selftest.o.
* configure.ac: Append selftest-arch.c and common/selftest.c to
CONFIG_SRCS. Append selftest-arch.o and selftest.o to COMMON_OBS.
* configure: Re-generated.
* maint.c (maintenance_selftest): Wrap selftests::run_tests with
GDB_SELF_TEST.
(maintenance_info_selftests): Likewise.
gdb/testsuite:
2018-01-08 Simon Marchi <simon.marchi@ericsson.com>
* gdb.gdb/unittest.exp: Match output in non-development mode.
One of the tests in gdb.ada/access_tagged_param.exp verifies
the value of the parameters being printed by GDB when stopping
at a breakpoint inside procedure Pck.Inspect.
In particular, one of these parameters is actually generated
internally by the compiler, and does only indirectly depend
on the user-level code. A recent change in AdaCore's compiler
caused the code expansion to change a little bit, and as a result,
the value of that parameter has changed from 2 to 3. This can be
evindenced by looking at the code post expansion, using the -gnatDG
command-line switch to generate the .dg files:
$ gnatmake -g -gnatDG foo.adb
$ vi foo.adb.dg
We can see that the call to pck.inspect used to be:
pck__inspect (P8b, objL => 2);
With a recent version of GNAT Pro, it is now:
pck__inspect (P9b, objL => 3);
This change causes a spurious FAIL when running this testcase.
The objL parameter being, at heart, a simple counter of the nesting
level, this commit relaxes the expected output to accept any single-
digit number. We could accept any decimal, but given the example
program, I dout that number will reach double-digit level. If it
does, we'll double-check that this is normal, and relax the expected
output further.
gdb/testsuite/ChangeLog:
* gdb.ada/access_tagged_param.exp: Relax expected output
for value of "ObjL" in "continue" to pck.inspect breakpoint
test.
Tested on x86_64-linux.
Consider the following code:
type Index is (Index1, Index2);
Size : constant Integer := 10;
for Index use (Index1 => 1, Index2 => Size);
type Array_Index_Enum is array (Index) of Integer;
my_table : Array_Index_Enum :=(others => 42);
When compiling the code above with a compiler where the GNAT encodings
are turned off (which can be temporarily emulated by using the compiler
switch -fgnat-encodings=minimal), printing this table in gdb leads to:
(gdb) p my_table
$1 = (42, 42, 4203344, 10, -8320, 32767, 4203465, 0, 0, 0)
The displayed content is wrong since the handling part believes
that the length of the array is max index value (10) minus the
first index value (1) i+ 1 = 10 which is wrong since index are not
contiguous in this case.
The right behavior is to detect that the array is using enumeration
index hence parse the enumeration values in order to get the number
of indexes in this array (2 indexes here).
This patch fixes this issue and changes the output as follow:
(gdb) p my_table
$1 = (42, 42)
gdb/ChangeLog:
* ada-valprint.c (val_print_packed_array_elements): Use
proper number of elements when printing an array indexed
by an enumeration type.
gdb/testsuite/ChangeLog (Joel Brobecker <brobecker@adacore.com>):
* gdb.ada/arr_enum_idx_w_gap.exp
* gdb.ada/arr_enum_idx_w_gap/foo_q418_043.adb
Tested on x86_64-linux.
This patch removes the global variable dwarf2_per_objfile. This global
variable is set at the various entry points of dwarf2read.c (using
dw2_setup), and is referred to throughout the file. Instead of passing
data between functions in global variables like this one, it would be
better if the functions that depend on it either received it as argument
or got it from the existing arguments they receive. For example, a
function receiving a reference to a dwarf2_per_cu_data can access it
from dwarf2_per_cu_data::dwarf2_per_objfile.
This patch has been tested on the buildbot.
gdb/ChangeLog:
* dwarf2read.c (struct mapped_debug_names): Add constructor.
<dwarf2_per_objfile>: New field.
(dwarf2_per_objfile): Remove global.
(get_dwarf2_per_objfile): New function.
(set_dwarf2_per_objfile): New function.
(dwarf2_build_psymtabs_hard): Change objfile parameter to
dwarf2_per_objfile.
(abbrev_table_read_table): Add dwarf2_per_objfile parameter.
(read_abbrev_offset): Likewise.
(read_indirect_string): Likewise.
(read_indirect_line_string): Likewise.
(read_indirect_string_at_offset): Likewise.
(read_indirect_string_from_dwz): Likewise.
(dwarf2_find_containing_comp_unit): Change objfile parameter to
dwarf2_per_objfile.
(age_cached_comp_units): Add dwarf2_per_objfile parameter.
(create_all_comp_units): Change objfile parameter to
dwarf2_per_objfile.
(create_all_type_units): Likewise.
(process_queue): Add dwarf2_per_objfile parameter.
(read_and_check_comp_unit_head): Likewise.
(lookup_dwo_unit_in_dwp): Likewise.
(get_dwp_file): Likewise.
(process_cu_includes): Likewise.
(struct free_dwo_file_cleanup_data): New struct.
(dwarf2_has_info): Use get_dwarf2_per_objfile and
set_dwarf2_per_objfile.
(dwarf2_get_dwz_file): Add dwarf2_per_objfile parameter.
(dw2_do_instantiate_symtab): Get dwarf2_per_objfile from
context, adjust calls.
(dw2_instantiate_symtab): Likewise.
(dw2_get_cutu): Add dwarf2_per_objfile parameter.
(dw2_get_cu): Likewise.
(create_cu_from_index_list): Change objfile parameter to
dwarf2_per_objfile.
(create_cus_from_index_list): Get dwarf2_per_objfile from
context, adjust calls.
(create_cus_from_index): Likewise.
(create_signatured_type_table_from_index): Change objfile
parameter to dwarf2_per_objfile.
(create_signatured_type_table_from_debug_names): Change objfile
parameter to dwarf2_per_objfile.
(create_addrmap_from_index): Likewise.
(create_addrmap_from_aranges): Likewise.
(dwarf2_read_index): Use get_dwarf2_per_objfile, adjust calls.
(dw2_setup): Remove.
(dw2_get_file_names_reader): Get dwarf2_per_objfile from
context.
(dw2_find_last_source_symtab): Get dwarf2_per_objfile using
get_dwarf2_per_objfile.
(dw2_forget_cached_source_info): Likewise.
(dw2_map_symtabs_matching_filename): Likewise.
(struct dw2_symtab_iterator) <index>: Remove.
<dwarf2_per_objfile>: New field.
(dw2_symtab_iter_init): Replace index parameter with
dwarf2_per_objfile.
(dw2_symtab_iter_next): Use dwarf2_per_objfile from iter.
(dw2_lookup_symbol): Use get_dwarf2_per_objfile and adjust.
(dw2_print_stats): Likewise.
(dw2_dump): Likewise.
(dw2_expand_symtabs_for_function): Likewise.
(dw2_expand_all_symtabs): Likewise.
(dw2_expand_symtabs_with_fullname): Likewise.
(dw2_expand_marked_cus): Replace index and objfile parameters
with dwarf2_per_objfile.
(dw_expand_symtabs_matching_file_matcher): Add
dwarf2_per_objfile parameter and adjust calls.
(dw2_expand_symtabs_matching): Use get_dwarf2_per_objfile and
adjust calls.
(dw2_find_pc_sect_compunit_symtab): Don't call dw2_setup.
(dw2_map_symbol_filenames): Use get_dwarf2_per_objfile and
adjust calls.
(create_cus_from_debug_names_list): Replace objfile parameter
with dwarf2_per_objfile and adjust calls.
(create_cus_from_debug_names): Likewise.
(dwarf2_read_debug_names): Likewise.
(mapped_debug_names::namei_to_name): Adjust call.
(dw2_debug_names_iterator::next): Likewise.
(dw2_debug_names_iterator::find_vec_in_debug_names): Likewise.
(dw2_debug_names_lookup_symbol): Use get_dwarf2_per_objfile.
(dw2_debug_names_dump): Likewise.
(dw2_debug_names_expand_symtabs_for_function): Likewise.
(dw2_debug_names_expand_symtabs_matching): Likewise.
(dwarf2_initialize_objfile): Likewise.
(dwarf2_build_psymtabs): Likewise.
(get_abbrev_section_for_cu): Get dwarf2_per_objfile from
this_cu.
(error_check_comp_unit_head): Add dwarf2_per_objfile parameter.
(read_and_check_comp_unit_head): Likewise.
(read_abbrev_offset): Likewise.
(create_debug_type_hash_table): Likewise.
(create_debug_types_hash_table): Likewise.
(create_all_type_units): Replace objfile parameter with
dwarf2_per_objfile.
(add_type_unit): Add dwarf2_per_objfile parameter.
(fill_in_sig_entry_from_dwo_entry): Replace objfile parameter
with dwarf2_per_objfile.
(lookup_dwo_signatured_type): Get dwarf2_per_objfile from cu.
(lookup_dwp_signatured_type): Likewise.
(lookup_signatured_type): Likewise.
(read_cutu_die_from_dwo): Likewise.
(init_tu_and_read_dwo_dies): Likewise.
(init_cutu_and_read_dies): Likewise.
(init_cutu_and_read_dies_no_follow): Likewise.
(allocate_type_unit_groups_table): Add objfile parameter.
(create_type_unit_group): Use dwarf2_per_objfile from cu.
(get_type_unit_group): Likewise.
(process_psymtab_comp_unit): Update call.
(build_type_psymtabs_reader): Use dwarf2_per_objfile from cu.
(build_type_psymtabs_1): Add dwarf2_per_objfile parameter.
(print_tu_stats): Likewise.
(build_type_psymtab_dependencies): Use dwarf2_per_objfile passed
in void* parameter.
(build_type_psymtabs): Change objfile parameter to
dwarf2_per_objfile.
(process_skeletonless_type_unit): Use dwarf2_per_objfile
passed in void* parameter.
(process_skeletonless_type_units): Change objfile parameter to
dwarf2_per_objfile.
(set_partial_user): Likewise.
(dwarf2_build_psymtabs_hard): Likewise.
(read_comp_units_from_section): Likewise.
(create_all_comp_units): Likewise.
(scan_partial_symbols): Update calls.
(add_partial_symbol): Likewise.
(dwarf2_read_symtab): Use get_dwarf2_per_objfile.
(maybe_queue_comp_unit): Use dwarf2_read_symtab from cu.
(process_queue): Add dwarf2_per_objfile parameter.
(get_compunit_symtab): Use dwarf2_per_objfile from cu.
(compute_compunit_symtab_includes): Likewise.
(process_cu_includes): Add dwarf2_per_objfile parameter.
(process_full_comp_unit): Use dwarf2_per_objfile from cu.
(process_full_type_unit): Likewise.
(process_imported_unit_die): Update call.
(handle_DW_AT_stmt_list): Use dwarf2_per_objfile from cu.
(read_file_scope): Likewise.
(allocate_dwo_file_hash_table): Add objfile parameter.
(lookup_dwo_file_slot): Add dwarf2_per_objfile parameter.
(create_cus_hash_table): Likewise.
(create_dwp_hash_table): Likewise.
(create_dwo_unit_in_dwp_v1): Likewise.
(create_dwp_v2_section): Likewise.
(create_dwo_unit_in_dwp_v2): Likewise.
(lookup_dwo_unit_in_dwp): Likewise.
(try_open_dwop_file): Likewise.
(open_dwo_file): Likewise. Use dwarf2_per_objfile from cu.
(open_and_init_dwo_file): Use dwarf2_per_objfile from cu, update
cleanup to include a reference to dwarf2_per_objfile.
(open_dwp_file): Add dwarf2_per_objfile parameter.
(open_and_init_dwp_file): Likewise.
(get_dwp_file): Likewise.
(lookup_dwo_cutu): Use dwarf2_per_objfile from cu.
(queue_and_load_all_dwo_tus): Update call.
(free_dwo_file_cleanup): Use dwarf2_per_objfile from cleanup
data.
(dwarf2_rnglists_process): Use dwarf2_per_objfile from cu.
(dwarf2_ranges_process): Likewise.
(dwarf2_get_pc_bounds): Likewise.
(mark_common_block_symbol_computed): Likewise.
(abbrev_table_read_table): Add dwarf2_per_objfile parameter.
(dwarf2_read_abbrevs): Update call.
(read_partial_die): Use dwarf2_per_objfile from cu.
(find_partial_die): Likewise.
(fixup_partial_die): Likewise.
(read_attribute_value): Likewise.
(read_indirect_string_at_offset_from): Add objfile parameter.
(read_indirect_string_at_offset): Add dwarf2_per_objfile
parameter.
(read_indirect_string_from_dwz): Add objfile parameter.
(read_indirect_string): Add objfile parameter.
(read_addr_index_1): Add dwarf2_per_objfile parameter.
(read_addr_index): Use dwarf2_per_objfile from cu.
(dwarf2_read_addr_index): Use dwarf2_per_objfile from cu, don't
call dw2_setup.
(read_str_index): Use dwarf2_per_objfile from cu.
(get_debug_line_section): Likewise.
(read_formatted_entries): Add dwarf2_per_objfile parameter.
(dwarf_decode_line_header): Use dwarf2_per_objfile from cu.
(new_symbol_full): Use dwarf2_per_objfile from cu.
(build_error_marker_type): Likewise.
(lookup_die_type): Likewise.
(determine_prefix): Likewise.
(follow_die_offset): Likewise.
(dwarf2_fetch_die_loc_sect_off): Use get_dwarf2_per_objfile.
(dwarf2_fetch_constant_bytes): Don't call dw2_setup.
(dwarf2_fetch_die_type_sect_off): Likewise.
(dwarf2_get_die_type): Likewise.
(follow_die_sig_1): Use dwarf2_per_objfile from cu.
(get_signatured_type): Likewise.
(get_DW_AT_signature_type): Likewise.
(dwarf_decode_macro_bytes): Add dwarf2_per_objfile parameter.
(dwarf_decode_macros): Use dwarf2_per_objfile from cu.
(cu_debug_loc_section): Likewise.
(fill_in_loclist_baton): Likewise.
(dwarf2_symbol_mark_computed): Likewise.
(dwarf2_find_containing_comp_unit): Change objfile parameter to
dwarf2_per_objfile.
(free_cached_comp_units): Use dwarf2_per_objfile passed in void*
parameter.
(age_cached_comp_units): Add dwarf2_per_objfile parameter.
(free_one_cached_comp_unit): Use dwarf2_per_objfile from cu.
(dwarf2_free_objfile): Use get_dwarf2_per_objfile.
(set_die_type): Use dwarf2_free_objfile from cu.
(get_die_type_at_offset): Likewise.
(dwarf2_per_objfile_free): Don't assign global variable.
(debug_names) <constructor>: Add dwarf2_per_objfile
parameter, update m_debugstrlookup construction.
(debug_names::debug_str_lookup): Add dwarf2_per_objfile
parameter.
<m_dwarf2_per_objfile>: New field.
<lookup>: Use m_dwarf2_per_objfile.
(check_dwarf64_offsets): Add dwarf2_per_objfile parameter.
(psyms_seen_size): Likewise.
(write_gdbindex): Replace objfile parameter with
dwarf2_per_objfile.
(write_debug_names): Likewise.
(write_psymtabs_to_index): Likewise.
(save_gdb_index_command): Use get_dwarf2_per_objfile, update
calls.
The next patch aims to remove the dwarf2_per_objfile global. In many
functions, we need to find a way to get a reference to the current
dwarf2_per_objfile through the objects passed in parameters. Often, we have
access to a dwarf2_cu or a dwarf2_per_cu_data. These objects have a reference
to the objfile, through which we can get the dwarf2_per_objfile:
dwarf2_per_objfile = ((struct dwarf2_per_objfile *)
objfile_data (objfile, dwarf2_objfile_data_key));
However, this is a bit cumbersome to do all over the place. It would be
more logical if the dwarf2_cu and dwarf2_per_cu_data had a reference to
their dwarf2_per_objfile, which would then have a reference to the
objfile. It would be more in line with the object hierarchy, where
dwarf2_per_objfile owns the dwarf2_per_cu_data instances. We could
even remove the reference dwarf2_cu has to dwarf2_per_objfile, since we
can access dwarf2_per_objfile through dwarf2_cu::per_cu.
In a graphical way, references would look like this after the current
patch:
objfile <--- dwarf2_per_objfile <--- dwarf2_per_cu_data
| ^
| |
`- dwarf2_cu
This patch has been tested on the buildbot.
gdb/ChangeLog:
* dwarf2read.c (struct dwarf2_cu) <objfile>: Remove.
<dwarf2_per_objfile>: New field.
(struct dwarf2_per_cu_data) <objfile>: Remove.
<dwarf2_per_objfile>: New field.
(create_cu_from_index_list): Assign dwarf2_per_objfile instead
of objfile.
(create_signatured_type_table_from_index): Likewise.
(create_debug_type_hash_table): Likewise.
(fill_in_sig_entry_from_dwo_entry): Likewise.
(lookup_dwo_unit): Access objfile through dwarf2_per_objfile.
(create_type_unit_group): Assign dwarf2_per_objfile instead of
objfile.
(create_partial_symtab): Access objfile through
dwarf2_per_objfile.
(process_psymtab_comp_unit_reader): Likewise.
(read_comp_units_from_section): Likewise.
(scan_partial_symbols): Likewise.
(add_partial_symbol): Likewise.
(add_partial_subprogram): Likewise.
(peek_die_abbrev): Likewise.
(fixup_go_packaging): Likewise.
(process_full_comp_unit): Likewise.
(process_full_type_unit): Likewise.
(process_imported_unit_die): Likewise.
(dwarf2_compute_name): Likewise.
(dwarf2_physname): Likewise.
(read_import_statement): Likewise.
(create_cus_hash_table): Assign dwarf2_physname instead of
objfile.
(read_func_scope): Access objfile through dwarf2_per_objfile.
(read_lexical_block_scope): Likewise.
(read_call_site_scope): Likewise.
(read_variable): Likewise.
(dwarf2_rnglists_process): Likewise.
(dwarf2_ranges_process): Likewise.
(dwarf2_ranges_read): Likewise.
(dwarf2_record_block_ranges): Likewise.
(dwarf2_add_field): Likewise.
(dwarf2_add_member_fn): Likewise.
(read_structure_type): Likewise.
(process_structure_scope): Likewise.
(read_enumeration_type): Likewise.
(read_array_type): Likewise.
(read_common_block): Likewise.
(read_namespace_type): Likewise.
(read_namespace): Likewise.
(read_module_type): Likewise.
(read_tag_pointer_type): Likewise.
(read_tag_ptr_to_member_type): Likewise.
(read_tag_string_type): Likewise.
(read_subroutine_type): Likewise.
(read_typedef): Likewise.
(read_base_type): Likewise.
(attr_to_dynamic_prop): Likewise.
(read_subrange_type): Likewise.
(read_unspecified_type): Likewise.
(load_partial_dies): Likewise.
(read_partial_die): Likewise.
(find_partial_die): Likewise.
(guess_partial_die_structure_name): Likewise.
(fixup_partial_die): Likewise.
(read_attribute_value): Likewise.
(read_addr_index_from_leb128): Likewise.
(dwarf2_read_addr_index): Likewise.
(dwarf2_string_attr): Likewise.
(lnp_state_machine::check_line_address): Likewise.
(dwarf_decode_lines_1): Likewise.
(dwarf_decode_lines): Likewise.
(dwarf2_start_symtab): Likewise.
(var_decode_location): Likewise.
(new_symbol_full): Likewise.
(dwarf2_const_value_data): Likewise.
(dwarf2_const_value_attr): Likewise.
(dwarf2_const_value): Likewise.
(die_type): Likewise.
(die_containing_type): Likewise.
(lookup_die_type): Likewise.
(guess_full_die_structure_name): Likewise.
(anonymous_struct_prefix): Likewise.
(dwarf2_name): Likewise.
(follow_die_ref_or_sig): Likewise.
(follow_die_offset): Likewise.
(follow_die_ref): Likewise.
(dwarf2_fetch_die_loc_sect_off): Likewise.
(dwarf2_fetch_constant_bytes): Likewise.
(dwarf2_fetch_die_type_sect_off): Likewise.
(dwarf2_get_die_type): Likewise.
(follow_die_sig): Likewise.
(decode_locdesc): Likewise.
(dwarf2_per_cu_objfile): Likewise.
(dwarf2_per_cu_text_offset): Likewise.
(init_one_comp_unit): Assign dwarf2_per_objfile instead of
objfile.
(set_die_type): Access objfile through
dwarf2_per_objfile.
This avoid having to manually free the return value.
gdb/gdbserver/ChangeLog:
* server.c (parse_debug_format_options): Return std::string.
(handle_monitor_command, captured_main): Adjust.
This patch changes the usage of VEC(converted_character_d) to use an
std::vector instead. This allows getting rid of a cleanup.
gdb/ChangeLog:
* valprint.c (converted_character_d): Remove typedef.
(DEF_VEC_O (converted_character_d)): Remove.
(count_next_character): Use std::vector.
(print_converted_chars_to_obstack): Likewise.
(generic_printstr): Likewise.
This patch replaces VEC(gdb_xml_value_s), which is passed to XML
visitors, with an std::vector. In order to be able to remove the
cleanup in gdb_xml_parser::start_element, the gdb_xml_parser structure
is made to own the value with a gdb::unique_xmalloc_ptr.
This patch has been tested on the buildbot.
gdb/ChangeLog:
* xml-support.h (struct gdb_xml_value): Add constructor.
<value>: Change type to unique_xmalloc_ptr.
(gdb_xml_value_s): Remove typedef.
(DEF_VEC_O (gdb_xml_value_s)): Remove.
(gdb_xml_element_start_handler): Change parameter type to
std::vector.
(xml_find_attribute): Likewise.
* xml-support.c (xml_find_attribute): Change parameter type to
std::vector and adjust.
(gdb_xml_values_cleanup): Remove.
(gdb_xml_parser::start_element): Adjust to std::vector.
(xinclude_start_include): Change paraeter type to std::vector
and adjust.
* btrace.c (check_xml_btrace_version): Likewise.
(parse_xml_btrace_block): Likewise.
(parse_xml_btrace_pt_config_cpu): Likewise.
(parse_xml_btrace_pt): Likewise.
(parse_xml_btrace_conf_bts): Likewise.
(parse_xml_btrace_conf_pt): Likewise.
* memory-map.c (memory_map_start_memory): Likewise.
(memory_map_start_property): Likewise.
* osdata.c (osdata_start_osdata): Likewise.
(osdata_start_item): Likewise.
(osdata_start_column): Likewise.
* remote.c (start_thread): Likewise.
* solib-aix.c (library_list_start_library): Likewise.
(library_list_start_list): Likewise.
* solib-svr4.c (library_list_start_library): Likewise.
(svr4_library_list_start_list): Likewise.
* solib-target.c (library_list_start_segment): Likewise.
(library_list_start_section): Likewise.
(library_list_start_library): Likewise.
(library_list_start_list): Likewise.
* tracepoint.c (traceframe_info_start_memory): Likewise.
(traceframe_info_start_tvar): Likewise.
* xml-syscall.c (syscall_start_syscall): Likewise.
* xml-tdesc.c (tdesc_start_target): Likewise.
(tdesc_start_feature): Likewise.
(tdesc_start_reg): Likewise.
(tdesc_start_union): Likewise.
(tdesc_start_struct): Likewise.
(tdesc_start_flags): Likewise.
(tdesc_start_enum): Likewise.
(tdesc_start_field): Likewise.
(tdesc_start_enum_value): Likewise.
(tdesc_start_vector): Likewise.
I think that the clone method of xmethod_worker can be removed. It is
only used in find_overload_match, to clone an xmethod we want to
keep. Instead, we can just std::move it out of the vector and into
value_from_xmethod. value_from_xmethod creates a value that will own
the xmethod_worker from that point. Other xmethod_workers left in the
vector will get destroyed when the vector gets destroyed, but the chosen
one will keep living inside the value struct.
gdb/ChangeLog:
* extension.h (struct xmethod_worker) <clone>: Remove.
* python/py-xmethods.c (struct python_xmethod_worker) <clone>:
Remove.
(python_xmethod_worker::clone): Remove.
* valops.c (find_overload_match): Use std::move instead of
clone.
The initial goal of this patch was to remove the usage of
VEC(xmethod_worker_ptr) and corresponding cleanups. I ended up having
to C++ify the xmethod_worker code, to be able to have xmethod_workers
free their data in destructors, and therefore be able to use vectors of
xmethod_worker unique_ptr.
The operations in extension_language_ops that act on one instance of
xmethod_worker (get result type, get args type, invoke) are transformed
to methods of xmethod_worker. xmethod_worker becomes an abstract base
class with virtual pure methods which python_xmethod_worker implements.
The only xmethod-related operation left in extension_language_ops is
get_matching_xmethod_workers, which returns a list of xmethod_workers.
The changes are relatively straightforward, but here are some notes on
things that may raise eyebrows:
- I was not really comfortable with the value_of_xmethod function. At
first it looks like a simple getter, so I considered making it a
method of xmethod_worker. But actually it creates a value and
transfers the ownership of the xmethod_worker to it. It would be a
bit weird and error-prone if calling a method on an object silently
removed the ownership of the object from the caller. To reflect the
behavior more accurately, I renamed it to value_from_xmethod and made
it accept an rvalue-reference (so the caller knows it gives away the
ownership). I noticed the backlink from xmethod_worker to its owning
value was not used, so I removed it.
- Some code, like get_matching_xmethod_workers, made each callee fill
a new vector, which was then merged in the result vector. I think
it's safe if we always pass the same vector around, and each
implementation just appends to it.
- The clone operation does not seem particularly useful, it is removed
in the following patch.
gdb/ChangeLog:
* extension-priv.h (enum ext_lang_rc): Remove, move to extension.h.
(struct extension_language_ops) <clone_xmethod_worker_data>: Remove.
<free_xmethod_worker_data>: Remove.
<get_matching_xmethod_workers>: Chance VEC to std::vector.
<get_xmethod_arg_types>: Remove.
<get_xmethod_result_type>: Remove.
<invoke_xmethod>: Remove.
* extension.c (new_xmethod_worker): Remove.
(clone_xmethod_worker): Remove.
(get_matching_xmethod_workers): Return void, pass std::vector by
pointer.
(get_xmethod_arg_types): Rename to...
(xmethod_worker::get_arg_types): ... this, and adjust.
(get_xmethod_result_type): Rename to...
(xmethod_worker::get_result_type): ... this, and adjust.
(invoke_xmethod): Remove.
(free_xmethod_worker): Remove.
(free_xmethod_worker_vec): Remove.
* extension.h (enum ext_lang_rc): Move here from
extension-priv.h.
(struct xmethod_worker): Add constructor and destructor.
<data>: Remove.
<value>: Remove.
<invoke, clone, do_get_result_type, do_get_arg_types>: New
virtual pure methods.
<get_arg_types, get_result_type>: New methods.
(xmethod_worker_ptr): Remove typedef.
(DEF_VEC_P (xmethod_worker_ptr)): Remove.
(xmethod_worker_vec): Remove typedef.
(xmethod_worker_up): New typedef.
(invoke_xmethod): Remove.
(clone_xmethod_worker): Remove.
(free_xmethod_worker): Remove.
(free_xmethod_worker_vec): Remove.
(get_xmethod_arg_types): Remove.
(get_xmethod_result_type): Remove.
* valops.c (find_method_list): Use std::vector, don't use
intermediate vector.
(value_find_oload_method_list): Use std::vector.
(find_overload_match): Use std::vector.
(find_oload_champ): Use std::vector.
* value.c (value_free): Use operator delete.
(value_of_xmethod): Rename to...
(value_from_xmethod): ... this. Don't assign
xmethod_worker::value, take rvalue-reference.
(result_type_of_xmethod): Adjust.
(call_xmethod): Adjust.
* value.h: Include extension.h.
(struct xmethod_worker): Don't forward-declare.
(value_of_xmethod): Rename to...
(value_from_xmethod): ... this, take rvalue-reference.
* python/py-xmethods.c (struct gdbpy_worker_data): Rename to...
(struct python_xmethod_worker): ... this, add constructor and
destructor.
<invoke, clone, do_get_arg_types, do_get_result_type>: Implement.
(gdbpy_free_xmethod_worker_data): Rename to...
(python_xmethod_worker::~python_xmethod_worker): ... this and
adjust.
(gdbpy_clone_xmethod_worker_data): Rename to...
(python_xmethod_worker::clone): ... this and adjust.
(gdbpy_get_matching_xmethod_workers): Use std::vector, don't use
temporary vector.
(gdbpy_get_xmethod_arg_types): Rename to...
(python_xmethod_worker::do_get_arg_types): ... this and adjust.
(gdbpy_get_xmethod_result_type): Rename to...
(python_xmethod_worker::do_get_result_type): ... this and
adjust.
(gdbpy_invoke_xmethod): Rename to...
(python_xmethod_worker::invoke): ... this and adjust.
(new_python_xmethod_worker): Rename to...
(python_xmethod_worker::python_xmethod_worker): ... this and
adjust.
* python/python-internal.h (gdbpy_clone_xmethod_worker_data):
Remove.
(gdbpy_free_xmethod_worker_data): Remove.
(gdbpy_get_matching_xmethod_workers): Use std::vector.
(gdbpy_get_xmethod_arg_types): Remove.
(gdbpy_get_xmethod_result_type): Remove.
(gdbpy_invoke_xmethod): Remove.
* python/python.c (python_extension_ops): Remove obsolete
callbacks.
ld/
* emulparams/elf32lriscv-defs.sh (GENERATE_SHLIB_SCRIPT): Move inside
case on $target, and don't set for riscv*-elf targets.
(GENERATE_PIE_SCRIPT): Likewise.
At https://sourceware.org/bugzilla/show_bug.cgi?id=18653#c7, Andrew
reports that the fix for PR gdb/18653 made GDB useless if you preload
libSegFault.so, because GDB internal-errors on startup:
$ LD_PRELOAD=libSegFault.so gdb
src/gdb/common/signals-state-save-restore.c:64: internal-error: unexpected signal handler
A problem internal to GDB has been detected,
further debugging may prove unreliable.
Aborted (core dumped)
$
The internal error comes from the code saving the signal dispositions
inherited from gdb's parent:
(top-gdb) bt
#0 0x000000000056b001 in internal_error(char const*, int, char const*, ...) (file=0xaf5f38 "src/gdb/common/signals-state-save-restore.c", line=64, fmt=0xaf5f18 "unexpected signal handler") at src/gdb/common/errors.c:54
#1 0x00000000005752c9 in save_original_signals_state() () at src/gdb/common/signals-state-save-restore.c:64
#2 0x00000000007425de in captured_main_1(captured_main_args*) (context=0x7fffffffd860)
at src/gdb/main.c:509
#3 0x0000000000743622 in captured_main(void*) (data=0x7fffffffd860) at src/gdb/main.c:1145
During symbol reading, cannot get low and high bounds for subprogram DIE at 24065.
#4 0x00000000007436f9 in gdb_main(captured_main_args*) (args=0x7fffffffd860) at src/gdb/main.c:1171
#5 0x0000000000413acd in main(int, char**) (argc=1, argv=0x7fffffffd968) at src/gdb/gdb.c:32
This commit downgrades the internal error to a warning. You'll get
instead:
~~~
$ LD_PRELOAD=libSegFault.so gdb
warning: Found custom handler for signal 11 (Segmentation fault) preinstalled.
Some signal dispositions inherited from the environment (SIG_DFL/SIG_IGN)
won't be propagated to spawned programs.
GNU gdb (GDB) 8.0.50.20171213-git
Copyright (C) 2017 Free Software Foundation, Inc.
License GPLv3+: GNU GPL version 3 or later <http://gnu.org/licenses/gpl.html>
This is free software: you are free to change and redistribute it.
There is NO WARRANTY, to the extent permitted by law. Type "show copying"
and "show warranty" for details.
This GDB was configured as "x86_64-pc-linux-gnu".
Type "show configuration" for configuration details.
For bug reporting instructions, please see:
<http://www.gnu.org/software/gdb/bugs/>.
Find the GDB manual and other documentation resources online at:
<http://www.gnu.org/software/gdb/documentation/>.
For help, type "help".
Type "apropos word" to search for commands related to "word"...
(gdb)
~~~
This also moves the location where save_original_signals_state is
called a bit further below (to after option processing), so that "-q"
disables the warning:
~~~
$ LD_PRELOAD=libSegFault.so gdb -q
(gdb)
~~~
New testcase included.
gdb/ChangeLog:
2018-01-05 Pedro Alves <palves@redhat.com>
PR gdb/18653
* common/signals-state-save-restore.c
(save_original_signals_state): New parameter 'quiet'. Warn if we
find a custom handler preinstalled, instead of internal erroring.
But only warn if !quiet.
* common/signals-state-save-restore.h
(save_original_signals_state): New parameter 'quiet'.
* main.c (captured_main_1): Move save_original_signals_state call
after option handling, and pass QUIET.
gdb/gdbserver/ChangeLog:
2018-01-05 Pedro Alves <palves@redhat.com>
PR gdb/18653
* server.c (captured_main): Pass quiet=false to
save_original_signals_state.
gdb/testsuite/ChangeLog:
2018-01-05 Pedro Alves <palves@redhat.com>
PR gdb/18653
* gdb.base/libsegfault.exp: New.
At <https://sourceware.org/ml/gdb-patches/2017-12/msg00298.html>, Joel
wrote:
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Consider the following code which first declares a tagged type (the
equivalent of a class in Ada), and then a procedure which takes a
pointer (access) to this type's 'Class.
package Pck is
type Top_T is tagged record
N : Integer := 1;
end record;
procedure Inspect (Obj: access Top_T'Class);
end Pck;
Putting a breakpoint in that procedure and then running to it triggers
an internal error:
(gdb) break inspect
(gdb) continue
Breakpoint 1, pck.inspect (obj=0x63e010
/[...]/gdb/stack.c:621: internal-error: void print_frame_args(symbol*, frame_info*, int, ui_file*): Assertion `nsym != NULL' failed.
What's special about this subprogram is that it takes an access to
what we call a 'Class type, and for implementation reasons, the
compiler adds an extra argument named "objL". If you are curious why,
it allows the compiler for perform dynamic accessibility checks that
are mandated by the language.
If we look at the location where we get the internal error (in
stack.c), we find that we are looping over the symbol of each
parameter, and for each parameter, we do:
/* We have to look up the symbol because arguments can have
two entries (one a parameter, one a local) and the one we
want is the local, which lookup_symbol will find for us.
[...]
nsym = lookup_symbol (SYMBOL_LINKAGE_NAME (sym),
b, VAR_DOMAIN, NULL).symbol;
gdb_assert (nsym != NULL);
The lookup_symbol goes through the lookup structure, which means the
symbol's linkage name ("objL") gets transformed into a
lookup_name_info object (in block_lookup_symbol), before it gets fed
to the block symbol dictionary iterators. This, in turn, triggers the
symbol matching by comparing the "lookup" name which, for Ada, means
among other things, lowercasing the given name to "objl". It is this
transformation that causes the lookup find no matches, and therefore
trip this assertion.
Going back to the "offending" call to lookup_symbol in stack.c, what
we are trying to do, here, is do a lookup by linkage name. So, I
think what we mean to be doing is a completely literal symbol lookup,
so maybe not even strcmp_iw, but actually just plain strcmp???
In the past, in practice, you could get that effect by doing a lookup
using the C language. But that doesn't work, because we still end up
somehow using Ada's lookup_name routine which transforms "objL".
So, ideally, as I hinted before, I think what we need is a way to
perform a literal lookup so that searches by linkage names like the
above can be performed.
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
This commit fixes the problem by implementing something similar to
Joel's literal idea, but with some important differences.
I considered adding a symbol_name_match_type::LINKAGE and supporting
searching by linkage name for any language, but the problem with that
is that the dictionaries only work with SYMBOL_SEARCH_NAME, because
that's what is used for hashing. We'd need separate dictionaries for
hashed linkage names.
So with the current symbol tables infrastructure, it's not literal
linkage names that we want to pass down, but instead literal _search_
names (SYMBOL_SEARCH_NAME, etc.).
However, psymbols have no overload/function parameter info in C++, so
a straight strcmp doesn't work properly for C++ name matching.
So what we do is be a little less aggressive then and add a new
symbol_name_match_type::SEARCH_SYMBOL instead that takes as input a
non-user-input search symbol, and then we skip any decoding/demangling
steps and make:
- Ada treat that as a verbatim match,
- other languages treat it as symbol_name_match_type::FULL.
This also fixes the new '"maint check-psymtabs" for Ada' testcase for
me (gdb.ada/maint_with_ada.exp). I've not removed the kfail yet
because Joel still sees that testcase failing with this patch.
That'll be fixed in follow up patches.
gdb/ChangeLog:
2018-01-05 Pedro Alves <palves@redhat.com>
PR gdb/22670
* ada-lang.c (literal_symbol_name_matcher): New function.
(ada_get_symbol_name_matcher): Use it for
symbol_name_match_type::SEARCH_NAME.
* block.c (block_lookup_symbol): New parameter 'match_type'. Pass
it down instead of assuming symbol_name_match_type::FULL.
* block.h (block_lookup_symbol): New parameter 'match_type'.
* c-valprint.c (print_unpacked_pointer): Use
lookup_symbol_search_name instead of lookup_symbol.
* compile/compile-object-load.c (get_out_value_type): Pass down
symbol_name_match_type::SEARCH_NAME.
* cp-namespace.c (cp_basic_lookup_symbol): Pass down
symbol_name_match_type::FULL.
* cp-support.c (cp_get_symbol_name_matcher): Handle
symbol_name_match_type::SEARCH_NAME.
* infrun.c (insert_exception_resume_breakpoint): Use
lookup_symbol_search_name.
* p-valprint.c (pascal_val_print): Use lookup_symbol_search_name.
* psymtab.c (maintenance_check_psymtabs): Use
symbol_name_match_type::SEARCH_NAME and SYMBOL_SEARCH_NAME.
* stack.c (print_frame_args): Use lookup_symbol_search_name and
SYMBOL_SEARCH_NAME.
* symtab.c (lookup_local_symbol): Don't demangle the lookup name
if symbol_name_match_type::SEARCH_NAME.
(lookup_symbol_in_language): Pass down
symbol_name_match_type::FULL.
(lookup_symbol_search_name): New.
(lookup_language_this): Pass down
symbol_name_match_type::SEARCH_NAME.
(lookup_symbol_aux, lookup_local_symbol): New parameter
'match_type'. Pass it down.
* symtab.h (symbol_name_match_type::SEARCH_NAME): New enumerator.
(lookup_symbol_search_name): New declaration.
(lookup_symbol_in_block): New 'match_type' parameter.
gdb/testsuite/ChangeLog:
2018-01-05 Joel Brobecker <brobecker@adacore.com>
PR gdb/22670
* gdb.ada/access_tagged_param.exp: New file.
* gdb.ada/access_tagged_param/foo.adb: New file.
The comments about mixed case in the testcase are actually a red
herring. The problem here is that we'd get to
ada_lookup_encoded_symbol with "my_table", which wraps the looked up
name in "<>"s to force a verbatim match, and that in turn disables
wild matching.
Fix this by swapping around the internals of ada_lookup_encoded_symbol
and ada_lookup_symbol, thus avoiding the encoding and
verbatim-wrapping in the ada_lookup_symbol case, the case that starts
with a user-provided lookup name.
Ada encoding is still done of course, in the ada_lookup_name_info
ctor. This could be also seen as avoiding the double-encoding problem
in a different way.
gdb/ChangeLog:
2018-01-05 Pedro Alves <palves@redhat.com>
PR gdb/22670
* ada-lang.c (ada_lookup_encoded_symbol): Reimplement in terms of
ada_lookup_symbol.
(ada_lookup_symbol): Reimplement in terms of
ada_lookup_symbol_list, bits factored out from
ada_lookup_encoded_symbol.
gdb/testsuite/ChangeLog:
2018-01-05 Pedro Alves <palves@redhat.com>
PR gdb/22670
* gdb.ada/info_addr_mixed_case.exp: Remove kfail. Extend test to
exercise lower case too, and to exercise both full matching and
wild matching.
Consider the following code, which creates a local variable B
which is a renaming whose expression references a subprogram
parameter:
procedure Flip (Bits : in out Bits_Type; I : Natural) is
begin
declare
B : Boolean renames Bits (I);
begin
B := not B; -- BREAK
end;
end Flip;
Trying to print the value of B when at the "BREAK" line currently
does not work:
(gdb) p b
Could not find i
What happens is the following: For the renaming, GNAT generates
a variable whose name is encoded as follow:
b___XR_bits___XEXSi
GDB properly detects that variable, determines that, to compute
the variable's value, we start from the symbol "Bits", which
we then have to subscript (XS) using 'i' as the index. The error
occurs while trying to find 'i'.
This is because we forgot to pass the block in the call to
ada_lookup_encoded_symbol, which this patch fixes.
gdb/ChangeLog:
* ada-exp.y (write_object_renaming): When subscripting an array
using a symbol as the index, pass the block in call to
ada_lookup_encoded_symbol when looking that symbol up.
gdb/testsuite/ChangeLog:
* gdb.ada/rename_subscript_param: New testcase.
Tested on x86_64-linux.
Note: This requires the following GCC patch:
| 2017-04-25 Pierre-Marie de Rodat <derodat@adacore.com>
|
| * exp_dbug.adb: In Debug_Renaming_Declaration,
| when dealing with indexed component, accept to produce a renaming
| symbol when the index is an IN parameter or when it is a name
| defined in an outer scope.
Consider the following variable "Indexed_By_Enum", declared as
an access to an array whose index type is an enumerated type
whose underlying values have "gaps":
type Enum_With_Gaps is (LIT0, LIT1, LIT2, LIT3, LIT4);
for Enum_With_Gaps use (LIT0 => 3,
LIT1 => 5,
LIT2 => 8,
LIT3 => 13,
LIT4 => 21);
for Enum_With_Gaps'size use 16;
type MyWord is range 0 .. 16#FFFF# ;
for MyWord'Size use 16;
type AR is array (Enum_With_Gaps range <>) of MyWord;
type AR_Access is access AR;
Indexed_By_Enum : AR_Access :=
new AR'(LIT1 => 1, LIT2 => 43, LIT3 => 42, LIT4 => 41);
Trying to print the length (number of elements) of this array using
the 'Length attribute does not work:
(gdb) print indexed_by_enum'length
'POS only defined on discrete types
The problem occurs while trying to get the array's index type.
It was using TYPE_INDEX_TYPE for that. It does not work for Ada arrays
in general; use ada_index_type instead.
gdb/ChangeLog:
* ada-lang.c (ada_array_length): Use ada_index_type instead of
TYPE_INDEX_TYPE.
gdb/testsuite/ChangeLog:
* gdb.ada/arr_acc_idx_w_gap: New testcase.
Tested on x86_64-linux.
Consider the following situation Ada code:
type Kind_T is (One, Two, Three);
type Time_Set_T is array (Kind_T) of Integer;
type T is record
Started : Time_Set_T;
end record;
Null_T : constant T := (Started => (others => 0));
My_Item : Pck.T := Pck.Null_T;
Trying to print the value of My_Item.Started is no problem:
(gdb) p item.started
$1 = (0, 0, 0)
However, if you save My_Item into a convenience variable first,
and then try to print a component of that record, you get
an unexpected memory error, instead of getting the same result.
For instance:
(gdb) set variable $item := item
(gdb) p $item.started
Cannot access memory at address 0x0
The issue occurs when, after we extracted the component from
the convenience variable, we next try to "fix" it (which is
ada-lang speak for resolving the type into a static type).
This is done in ada_to_fixed_value, which delegates to
ada_to_fixed_value_create via:
val = ada_to_fixed_value_create (value_type (val),
value_address (val), val);
And looking at ada_to_fixed_value_create, we see that:
struct type *type = ada_to_fixed_type (type0, 0, address, NULL, 1);
if (type == type0 && val0 != NULL)
return val0;
else
return value_from_contents_and_address (type, 0, address);
The part that interests us, in this case, is the "else" branch,
where we obviously make the implicit assumption that our object
has an address, which is not true, in this case, because we are
actually dealing with a convenience variable.
This patch plugs that hole by adding special handing for situations
where val does not live in memory. In that case, we just create
a not_lval value using val's contents.
gdb/ChangeLog:
* ada-lang.c (ada_to_fixed_value_create): Add handling of
the case where VALUE_LVAL (val0) is not lval_memory.
gdb/testsuite/ChangeLog:
* gdb.ada/convvar_comp: New testcase.
Tested on x86_64-linux.
Consider the following code:
type Table is array (Character) of Natural;
My_Table : Table := (others => 4874);
Printing this table in gdb leads to:
(gdb) p my_table
$1 = ('["00"]' => 4874 <repeats 256 times>)
In this case, the index of the first element in this array is also
the first element of the index type (character type). Similar to what
we do we enumeration types, we do not need to print the index of the
first element when printing the array.
This patch fixes this issue and changes the output as follow:
(gdb) p my_table
$1 = (4874 <repeats 256 times>)
gdb/ChangeLog:
* ada-valprint.c (print_optional_low_bound): Handle
character-indexed array printing like boolean-indexed array
printing.
gdb/testuite/ChangeLog:
* testsuite/gdb.ada/array_char_idx/pck.ads (Table): New type.
(My_Table): New global variable.
* testsuite/gdb.ada/array_char_idx.exp: Add test.
Tested on x86_64-linux.
Now that the GDB 8.1 branch has been created, we can
bump the version number.
gdb/ChangeLog:
GDB 8.1 branch created (5219ac6237):
* version.in: Bump version to 8.1.50.DATE-git.