Since symbols created by HIDDEN and PROVIDE_HIDDEN assignments in
linker script may be marked as defined, but not hidden, we can't
set eh->local_ref to 1 in _bfd_x86_elf_link_symbol_references_local.
Also R_386_GOT32X should be handled as just like R_386_GOT32 when
relocating a section. The input R_386_GOT32X relocations, which
can be relaxed, should have been converted to R_386_PC32, R_386_32
or R_386_GOTOFF.
bfd/
PR ld/23189
* elf32-i386.c (elf_i386_relocate_section): Handle R_386_GOT32X
like R_386_GOT32.
* elfxx-x86.c (_bfd_x86_elf_link_symbol_references_local): Don't
set eh->local_ref to 1 for linker defined symbols.
ld/
PR ld/23189
* testsuite/ld-i386/i386.exp: Run pr23189.
* testsuite/ld-x86-64/x86-64.exp: Likewise.
* testsuite/ld-i386/pr23189.d: New file.
* testsuite/ld-i386/pr23189.s: Likewise.
* testsuite/ld-i386/pr23189.t: Likewise.
* testsuite/ld-x86-64/pr23189.d: Likewise.
* testsuite/ld-x86-64/pr23189.s: Likewise.
* testsuite/ld-x86-64/pr23189.t: Likewise.
This patch prevents elf_next_in_group list pointer confusion when
SHT_GROUP sections specify other SHT_GROUP sections in their list of
group sections.
PR 23199
* elf.c (setup_group): Formatting. Check that SHT_GROUP entries
don't point at other SHT_GROUP sections. Set shdr corresponding
to invalid entry, to NULL rather than section 0. Identify
SHT_GROUP section index when reporting an error. Cope with NULL
shdr pointer.
This patch essentially causes GDB to treat inlined frames like "normal"
frames from the user's perspective. This means, for example, that when a
user sets a breakpoint in an inlined function, GDB will now actually stop
"in" that function.
Using the test case from breakpoints/17534,
3 static inline void NVIC_EnableIRQ(int IRQn)
4 {
5 volatile int y;
6 y = IRQn;
7 }
8
9 __attribute__( ( always_inline ) ) static inline void __WFI(void)
10 {
11 __asm volatile ("nop");
12 }
13
14 int main(void) {
15
16 x= 42;
17
18 if (x)
19 NVIC_EnableIRQ(16);
20 else
21 NVIC_EnableIRQ(18);
(gdb) b NVIC_EnableIRQ
Breakpoint 1 at 0x4003e4: NVIC_EnableIRQ. (2 locations)
(gdb) r
Starting program: 17534
Breakpoint 1, main () at 17534.c:19
19 NVIC_EnableIRQ(16);
Because skip_inline_frames currently skips every inlined frame, GDB "stops"
in the caller. This patch adds a new parameter to skip_inline_frames
that allows us to pass in a bpstat stop chain. The breakpoint locations
on the stop chain can be used to determine if we've stopped inside an inline
function (due to a user breakpoint). If we have, we do not elide the frame.
With this patch, GDB now reports that the inferior has stopped inside the
inlined function:
(gdb) r
Starting program: 17534
Breakpoint 1, NVIC_EnableIRQ (IRQn=16) at 17534.c:6
6 y = IRQn;
Many thanks to Jan and Pedro for guidance on this.
gdb/ChangeLog:
* breakpoint.c (build_bpstat_chain): New function, moved from
bpstat_stop_status.
(bpstat_stop_status): Add optional parameter, `stop_chain'.
If no stop chain is passed, call build_bpstat_chain to build it.
* breakpoint.h (build_bpstat_chain): Declare.
(bpstat_stop_status): Move documentation here from breakpoint.c.
* infrun.c (handle_signal_stop): Before eliding inlined frames,
build the stop chain and pass it to skip_inline_frames.
Pass this stop chain to bpstat_stop_status.
* inline-frame.c: Include breakpoint.h.
(stopped_by_user_bp_inline_frame): New function.
(skip_inline_frames): Add parameter `stop_chain'.
Move documention to inline-frame.h.
If non-NULL, use stopped_by_user_bp_inline_frame to determine
whether the frame should be elided.
* inline-frame.h (skip_inline_frames): Add parameter `stop_chain'.
Add moved documentation and update for new parameter.
gdb/testsuite/ChangeLog:
* gdb.ada/bp_inlined_func.exp: Update inlined frame locations
in expected breakpoint stop locations.
* gdb.dwarf2/implptr.exp (implptr_test_baz): Use up/down to
move to proper scope to test variable values.
* gdb.opt/inline-break.c (inline_func1, not_inline_func1)
(inline_func2, not_inline_func2, inline_func3, not_inline_func3):
New functions.
(main): Call not_inline_func3.
* gdb.opt/inline-break.exp: Start inferior and set breakpoints at
inline_func1, inline_func2, and inline_func3. Test that when each
breakpoint is hit, GDB properly reports both the stop location
and the backtrace. Repeat tests for temporary breakpoints.
I noticed that the printf command did not recognize the \e escape
sequence, used amongst other things to use colors:
(gdb) printf "This is \e[32mgreen\e[m!\n"
Unrecognized escape character \e in format string.
This patch makes format_pieces recognize it, which makes that command
print the expected result in glorious color.
I wrote a really simple unit test for format_pieces.
format_pieces::operator[] is unused so I removed it. I added
format_piece::operator==, which is needed to compare vectors of
format_piece.
gdb/ChangeLog:
PR cli/14975
* Makefile.in (SUBDIR_UNITTESTS_SRCS): Add
unittests/format_pieces-selftests.c.
* common/format.h (format_piece) <operator==>: New.
(format_pieces) <operator[]>: Remove.
* common/format.c (format_pieces::format_pieces): Handle \e.
* unittests/format_pieces-selftests.c: New.
PR symtab/23010 reports a crash that occurs when using -readnow
on a dwz-generated debuginfo file.
The crash occurs because the DWARF has a partial CU with no language
set, and then a full CU that references this partial CU using
DW_AT_abstract_origin.
In this case, the partial CU is read by dw2_expand_all_symtabs using
language_minimal; but then this conflicts with the creation of the
block's symbol table in the C++ CU.
This patch fixes the problem by arranging for partial CUs not to be
read by -readnow. I tend to think that it doesn't make sense to read
a partial CU in isolation -- they should only be read when imported
into some other CU.
In conjunction with some other patches I am going to post, this also
fixes the Rust -readnow crash that Jan reported.
There are two problems with this patch:
1. It is difficult to reason about. There are many cases where I've
patched the code to call init_cutu_and_read_dies with the flag set
to "please do read partial units" -- but I find it difficult to be
sure that this is always correct.
2. It is still missing a standalone test case. This seemed hard.
2018-05-17 Tom Tromey <tom@tromey.com>
PR symtab/23010:
* dwarf2read.c (load_cu, dw2_do_instantiate_symtab)
(dw2_instantiate_symtab): Add skip_partial parameter.
(dw2_find_last_source_symtab, dw2_map_expand_apply)
(dw2_lookup_symbol, dw2_expand_symtabs_for_function)
(dw2_expand_all_symtabs, dw2_expand_symtabs_with_fullname)
(dw2_expand_symtabs_matching_one)
(dw2_find_pc_sect_compunit_symtab)
(dw2_debug_names_lookup_symbol)
(dw2_debug_names_expand_symtabs_for_function): Update.
(init_cutu_and_read_dies): Add skip_partial parameter.
(process_psymtab_comp_unit, build_type_psymtabs_1)
(process_skeletonless_type_unit, load_partial_comp_unit)
(psymtab_to_symtab_1): Update.
(load_full_comp_unit): Add skip_partial parameter.
(process_imported_unit_die, dwarf2_read_addr_index)
(follow_die_offset, dwarf2_fetch_die_loc_sect_off)
(dwarf2_fetch_constant_bytes, dwarf2_fetch_die_type_sect_off)
(read_signatured_type): Update.
Obvious patch to remove unused local variables (found by adding
-Wunused). I didn't touch this one in value_fetch_lazy, because
check_typedef could have a desired side-effect.
3743 struct type *type = check_typedef (value_type (val));
gdb/ChangeLog:
* value.c (release_value): Remove unused variable.
(record_latest_value): Likewise.
(access_value_history): Likewise.
(preserve_values): Likewise.
When running gdb in the build directory without passing
--data-directory, I noticed I could provoke a crash by:
$ ./gdb -nx ./gdb
(gdb) ptype/o struct dwarf2_per_objfile
... and then trying to "q" out at the pagination prompt.
valgrind complained about an uninitialized use of py_type_printers.
Initializing this member fixes the bug.
I believe this bug can occur even when the gdb Python libraries are
available, for example if get_type_recognizers fails.
Tested by hand on x86-64 Fedora 26. No test case because it seemed
difficult to guarantee failures.
gdb/ChangeLog
2018-05-17 Tom Tromey <tom@tromey.com>
* extension.h (struct ext_lang_type_printers) <py_type_printers>:
Initialize.
Update `fetch_register' and `store_register' code to support arbitrary
register widths rather than only ones that are a multiply of the size of
the `ptrace' data type used with PTRACE_PEEKUSR and PTRACE_POKEUSR
requests to access registers. Remove associated assertions, correcting
an issue with accessing the DSPControl (`$dspctl') register on n64 MIPS
native targets:
(gdb) print /x $dspctl
.../gdb/linux-nat-trad.c:50: internal-error: void linux_nat_trad_target::fetch_register(regcache*, int): Assertion `(size % sizeof (PTRACE_TYPE_RET)) == 0' failed.
A problem internal to GDB has been detected,
further debugging may prove unreliable.
Quit this debugging session? (y or n) n
This is a bug, please report it. For instructions, see:
<http://www.gnu.org/software/gdb/bugs/>.
.../gdb/linux-nat-trad.c:50: internal-error: void linux_nat_trad_target::fetch_register(regcache*, int): Assertion `(size % sizeof (PTRACE_TYPE_RET)) == 0' failed.
A problem internal to GDB has been detected,
further debugging may prove unreliable.
Create a core file of GDB? (y or n) n
Command aborted.
(gdb)
All registers are now reported correctly and their architectural
hardware widths respected:
(gdb) print /x $dspctl
$1 = 0x55aa33cc
(gdb) info registers
zero at v0 v1
R0 0000000000000000 0000000000000001 000000fff7ffeb20 0000000000000000
a0 a1 a2 a3
R4 0000000000000001 000000ffffffeaf8 000000ffffffeb08 0000000000000000
a4 a5 a6 a7
R8 000000fff7ee3800 000000fff7ede8f0 000000ffffffeaf0 2f2f2f2f2f2f2f2f
t0 t1 t2 t3
R12 0000000000000437 0000000000000002 000000fff7ffd000 0000000120000ad0
s0 s1 s2 s3
R16 000000fff7ee2068 0000000120000e60 0000000000000000 0000000000000000
s4 s5 s6 s7
R20 0000000000521ec8 0000000000522608 0000000000000000 0000000000000000
t8 t9 k0 k1
R24 0000000000000000 0000000120000d9c 0000000000000000 0000000000000000
gp sp s8 ra
R28 0000000120019030 000000ffffffe990 000000ffffffe990 000000fff7d5b88c
status lo hi badvaddr
0000000000109cf3 0000000000005ea5 0000000000000211 000000fff7fc6fe0
cause pc
0000000000800024 0000000120000dbc
fcsr fir hi1 lo1
00000000 00f30000 0000000000000000 0101010101010101
hi2 lo2 hi3 lo3
0202020202020202 0303030303030303 0404040404040404 0505050505050505
dspctl restart
55aa33cc 0000000000000000
(gdb)
NB due to the lack of access to 64-bit DSP hardware all DSP register
values in the dumps are artificial and have been created with a debug
change applied to the kernel handler of the `ptrace' syscall.
The use of `store_unsigned_integer' and `extract_unsigned_integer'
unconditionally in all cases rather than when actual data occupies a
part of the data quantity exchanged with `ptrace' makes code perhaps
marginally slower, however I think avoiding it is not worth code
obfuscation it would cause. If this turns out unfounded, then there
should be no problem with optimizing this code later.
gdb/
PR gdb/22286
* linux-nat-trad.c (linux_nat_trad_target::fetch_register):
Also handle registers whose width is not a multiple of
PTRACE_TYPE_RET.
(linux_nat_trad_target::store_register): Likewise.
Remove `-Wshadow' compilation errors:
cc1: warnings being treated as errors
.../gas/config/tc-nds32.c: In function 'md_assemble':
.../gas/config/tc-nds32.c:5212: error: declaration of 'expr' shadows a global declaration
.../gas/expr.h:180: error: shadowed declaration is here
make[4]: *** [tc-nds32.o] Error 1
which for versions of GCC before 4.8 prevent support for NDS32 targets
from being built. See also GCC PR c/53066.
gas/
* tc-nds32.c (md_assemble): Rename `expr' local variable to
`insn_expr'.
Fix:
cc1: warnings being treated as errors
.../bfd/elf32-nds32.c: In function 'nds32_convert_32_to_16':
.../bfd/elf32-nds32.c:6816: error: 'insn_type' may be used uninitialized in this function
make[4]: *** [elf32-nds32.lo] Error 1
seen with GCC 4.1.2 and 4.4.7.
bfd/
* elf32-nds32.c (nds32_convert_32_to_16): Preset `insn_type'.
This changes program_space::cbfd to be a gdb_bfd_ref_ptr. This makes
it somewhat less error-prone to use, because now it manages the
reference counting automatically.
Tested by the buildbot.
2018-05-16 Tom Tromey <tom@tromey.com>
* gdbcore.h (core_bfd): Redefine.
* corelow.c (core_target::close): Update.
(core_target_open): Update.
* progspace.h (struct program_space) <cbfd>: Now a
gdb_bfd_ref_ptr.
One part of PR cli/19551 is that the mini debug info objfile reuses the
name of the main objfile from which it comes. This can be seen because
gdb claims to be reading symbols from the same file two times, like:
Reading symbols from /bin/gdb...Reading symbols from /bin/gdb...(no debugging symbols found)...done.
I think this would be less confusing if the minidebug objfile were given
a different name. That is what this patch implements. It also arranges
for the minidebug objfile to be marked OBJF_NOT_FILENAME.
After this patch the output looks like:
Reading symbols from /bin/gdb...Reading symbols from .gnu_debugdata for /usr/libexec/gdb...(no debugging symbols found)...done.
Tested by the buildbot.
gdb/ChangeLog
2018-05-16 Tom Tromey <tom@tromey.com>
PR cli/19551:
* symfile-add-flags.h (enum symfile_add_flags)
<SYMFILE_NOT_FILENAME>: New constant.
* symfile.c (read_symbols): Use SYMFILE_NOT_FILENAME. Get
objfile name from BFD.
(symbol_file_add_with_addrs): Check SYMFILE_NOT_FILENAME.
* minidebug.c (find_separate_debug_file_in_section): Put
".gnu_debugdata" into BFD's file name.
https://sourceware.org/ml/binutils/2013-05/msg00271.html was supposed
to banish "file format is ambiguous" errors for ELF. It didn't,
because the code supposedly detecting formats that implement
match_priority didn't work. That was due to not placing all matching
targets into the vector of matching targets. ELF objects should all
match the generic ELF target (priority 2), plus one or more machine
specific targets (priority 1), and perhaps a single machine specific
target with OS/ABI set (priority 0, best match). So the armel object
in the testcase actually matches elf32-littlearm,
elf32-littlearm-symbian, and elf32-littlearm-vxworks (all priority 1),
and elf32-little (priority 2). As the PR reported, elf32-little
wasn't seen as matching. Fixing that part of the problem wasn't too
difficult but matching the generic ELF target as well as the ARM ELF
targets resulted in ARM testsuite failures.
These proved to be the annoying reordering of stubs that occurs from
time to time due to the stub names containing the section id.
Matching another target causes more sections to be created in
elf_object_p. If section ids change, stub names change, which results
in different hashing and can therefore result in different hash table
traversal and stub creation order. That particular problem is fixed
by resetting section_id to the initial state before attempting each
target match, and taking a snapshot of its value after a successful
match.
PR 22458
* format.c (struct bfd_preserve): Add section_id.
(bfd_preserve_save, bfd_preserve_restore): Save and restore
_bfd_section_id.
(bfd_reinit): Set _bfd_section_id.
(bfd_check_format_matches): Put all matches of any priority into
matching_vector. Save initial section id and start each attempted
match at that section id.
* libbfd-in.h (_bfd_section_id): Declare.
* section.c (_bfd_section_id): Rename from section_id and make
global. Adjust uses.
(bfd_get_next_section_id): Delete.
* elf64-ppc.c (ppc64_elf_setup_section_lists): Replace use of
bfd_get_section_id with _bfd_section_id.
* libbfd.h: Regenerate.
* bfd-in2.h: Regenerate.
This patch corrects the disassembly masks for by element dot product
instructions. The bit 10 was wrong and supposed to be 1.
This caused incorrect disassembly of instructions in the unallocated space to
disassemble as dot product instructions.
No encoding errors can arrise from this issue.
opcodes/
PR binutils/23109
* aarch64-tbl.h (aarch64_opcode_table): Correct sdot and udot.
* aarch64-dis-2.c: Regenerate.
This patch adds constraints for read and write only system registers with the
msr and mrs instructions. The code will treat having both flags set and none
set as the same. These flags add constraints that must be matched up. e.g. a
system register with a READ only flag set, can only be used with mrs. If The
constraint fails a warning is emitted.
Examples of the warnings generated:
test.s: Assembler messages:
test.s:5: Warning: specified register cannot be written to at operand 1 -- `msr dbgdtrrx_el0,x3'
test.s:7: Warning: specified register cannot be read from at operand 2 -- `mrs x3,dbgdtrtx_el0'
test.s:8: Warning: specified register cannot be written to at operand 1 -- `msr midr_el1,x3'
and disassembly notes:
0000000000000000 <main>:
0: d5130503 msr dbgdtrtx_el0, x3
4: d5130503 msr dbgdtrtx_el0, x3
8: d5330503 mrs x3, dbgdtrrx_el0
c: d5330503 mrs x3, dbgdtrrx_el0
10: d5180003 msr midr_el1, x3 ; note: writing to a read-only register.
Note that because dbgdtrrx_el0 and dbgdtrtx_el0 have the same encoding, during
disassembly the constraints are use to disambiguate between the two. An exact
constraint match is always prefered over partial ones if available.
As always the warnings can be suppressed with -w and also be made errors using
warnings as errors.
binutils/
PR binutils/21446
* doc/binutils.texi (-M): Document AArch64 options.
gas/
PR binutils/21446
* testsuite/gas/aarch64/illegal-sysreg-2.s: Fix pmbidr_el1 test.
* testsuite/gas/aarch64/illegal-sysreg-2.l: Likewise.
* testsuite/gas/aarch64/illegal-sysreg-2.d: Likewise.
* testsuite/gas/aarch64/sysreg-diagnostic.s: New.
* testsuite/gas/aarch64/sysreg-diagnostic.l: New.
* testsuite/gas/aarch64/sysreg-diagnostic.d: New.
include/
PR binutils/21446
* opcode/aarch64.h (F_SYS_READ, F_SYS_WRITE): New.
opcodes/
PR binutils/21446
* aarch64-asm.c (opintl.h): Include.
(aarch64_ins_sysreg): Enforce read/write constraints.
* aarch64-dis.c (aarch64_ext_sysreg): Likewise.
* aarch64-opc.h (F_DEPRECATED, F_ARCHEXT, F_HASXT): Moved here.
(F_REG_READ, F_REG_WRITE): New.
* aarch64-opc.c (aarch64_print_operand): Generate notes for
AARCH64_OPND_SYSREG.
(F_DEPRECATED, F_ARCHEXT, F_HASXT): Move to aarch64-opc.h.
(aarch64_sys_regs): Add constraints to currentel, midr_el1, ctr_el0,
mpidr_el1, revidr_el1, aidr_el1, dczid_el0, id_dfr0_el1, id_pfr0_el1,
id_pfr1_el1, id_afr0_el1, id_mmfr0_el1, id_mmfr1_el1, id_mmfr2_el1,
id_mmfr3_el1, id_mmfr4_el1, id_isar0_el1, id_isar1_el1, id_isar2_el1,
id_isar3_el1, id_isar4_el1, id_isar5_el1, mvfr0_el1, mvfr1_el1,
mvfr2_el1, ccsidr_el1, id_aa64pfr0_el1, id_aa64pfr1_el1,
id_aa64dfr0_el1, id_aa64dfr1_el1, id_aa64isar0_el1, id_aa64isar1_el1,
id_aa64mmfr0_el1, id_aa64mmfr1_el1, id_aa64mmfr2_el1, id_aa64afr0_el1,
id_aa64afr0_el1, id_aa64afr1_el1, id_aa64zfr0_el1, clidr_el1,
csselr_el1, vsesr_el2, erridr_el1, erxfr_el1, rvbar_el1, rvbar_el2,
rvbar_el3, isr_el1, tpidrro_el0, cntfrq_el0, cntpct_el0, cntvct_el0,
mdccsr_el0, dbgdtrrx_el0, dbgdtrtx_el0, osdtrrx_el1, osdtrtx_el1,
mdrar_el1, oslar_el1, oslsr_el1, dbgauthstatus_el1, pmbidr_el1,
pmsidr_el1, pmswinc_el0, pmceid0_el0, pmceid1_el0.
* aarch64-tbl.h (aarch64_opcode_table): Add constraints to
msr (F_SYS_WRITE), mrs (F_SYS_READ).
This patch adds a new platform option "notes" that can be used to indicate if
disassembly notes should be placed in the disassembly as comments.
These notes can contain information about a failing constraint such as reading
from a write-only register. The disassembly will not be blocked because of this
but -M notes will emit a comment saying that the operation is not allowed.
For assembly this patch adds a new non-fatal status for errors. This is
essentially a warning. The reason for not creating an actual warning type is
that this causes the interaction between the ordering of warnings and errors to
be problematic. Currently the error buffer is almost always filled because of
the way operands are matched during assembly. An earlier template may have put
an error there that would only be displayed if no other template matches or
generates a higher priority error. But by definition a warning is lower
priority than a warning, so the error (which is incorrect if another template
matched) will supersede the warning. By treating warnings as errors and only
later relaxing the severity this relationship keeps working and the existing
reporting infrastructure can be re-used.
binutils/
PR binutils/21446
* doc/binutils.texi (-M): Document AArch64 options.
* NEWS: Document notes and warnings.
gas/
PR binutils/21446
* config/tc-aarch64.c (print_operands): Indicate no notes.
(output_operand_error_record): Support non-fatal errors.
(output_operand_error_report, warn_unpredictable_ldst, md_assemble):
Likewise.
include/
PR binutils/21446
* opcode/aarch64.h (aarch64_operand_error): Add non_fatal.
(aarch64_print_operand): Support notes.
opcodes/
PR binutils/21446
* aarch64-dis.c (no_notes: New.
(parse_aarch64_dis_option): Support notes.
(aarch64_decode_insn, print_operands): Likewise.
(print_aarch64_disassembler_options): Document notes.
* aarch64-opc.c (aarch64_print_operand): Support notes.
This patch if the first patch in a series to add the ability to add constraints
to system registers that an instruction must adhere to in order for the register
to be usable with that instruction.
These constraints can also be used to disambiguate between registers with the
same encoding during disassembly.
This patch adds a new flags entry in the sysreg structures and ensures it is
filled in and read out during assembly/disassembly. It also adds the ability for
the assemble and disassemble functions to be able to gracefully fail and re-use
the existing error reporting infrastructure.
The return type of these functions are changed to a boolean to denote success or
failure and the error structure is passed around to them. This requires
aarch64-gen changes so a lot of the changes here are just mechanical.
gas/
PR binutils/21446
* config/tc-aarch64.c (parse_sys_reg): Return register flags.
(parse_operands): Fill in register flags.
gdb/
PR binutils/21446
* aarch64-tdep.c (aarch64_analyze_prologue,
aarch64_software_single_step, aarch64_displaced_step_copy_insn):
Indicate not interested in errors.
include/
PR binutils/21446
* opcode/aarch64.h (aarch64_opnd_info): Change sysreg to struct.
(aarch64_decode_insn): Accept error struct.
opcodes/
PR binutils/21446
* aarch64-asm.h (aarch64_insert_operand, aarch64_##x): Return boolean
and take error struct.
* aarch64-asm.c (aarch64_ext_regno, aarch64_ins_reglane,
aarch64_ins_reglist, aarch64_ins_ldst_reglist,
aarch64_ins_ldst_reglist_r, aarch64_ins_ldst_elemlist,
aarch64_ins_advsimd_imm_shift, aarch64_ins_imm, aarch64_ins_imm_half,
aarch64_ins_advsimd_imm_modified, aarch64_ins_fpimm,
aarch64_ins_imm_rotate1, aarch64_ins_imm_rotate2, aarch64_ins_fbits,
aarch64_ins_aimm, aarch64_ins_limm_1, aarch64_ins_limm,
aarch64_ins_inv_limm, aarch64_ins_ft, aarch64_ins_addr_simple,
aarch64_ins_addr_regoff, aarch64_ins_addr_offset, aarch64_ins_addr_simm,
aarch64_ins_addr_simm10, aarch64_ins_addr_uimm12,
aarch64_ins_simd_addr_post, aarch64_ins_cond, aarch64_ins_sysreg,
aarch64_ins_pstatefield, aarch64_ins_sysins_op, aarch64_ins_barrier,
aarch64_ins_prfop, aarch64_ins_hint, aarch64_ins_reg_extended,
aarch64_ins_reg_shifted, aarch64_ins_sve_addr_ri_s4xvl,
aarch64_ins_sve_addr_ri_s6xvl, aarch64_ins_sve_addr_ri_s9xvl,
aarch64_ins_sve_addr_ri_s4, aarch64_ins_sve_addr_ri_u6,
aarch64_ins_sve_addr_rr_lsl, aarch64_ins_sve_addr_rz_xtw,
aarch64_ins_sve_addr_zi_u5, aarch64_ext_sve_addr_zz,
aarch64_ins_sve_addr_zz_lsl, aarch64_ins_sve_addr_zz_sxtw,
aarch64_ins_sve_addr_zz_uxtw, aarch64_ins_sve_aimm,
aarch64_ins_sve_asimm, aarch64_ins_sve_index, aarch64_ins_sve_limm_mov,
aarch64_ins_sve_quad_index, aarch64_ins_sve_reglist,
aarch64_ins_sve_scale, aarch64_ins_sve_shlimm, aarch64_ins_sve_shrimm,
aarch64_ins_sve_float_half_one, aarch64_ins_sve_float_half_two,
aarch64_ins_sve_float_zero_one, aarch64_opcode_encode): Likewise.
* aarch64-dis.h (aarch64_extract_operand, aarch64_##x): Likewise.
* aarch64-dis.c (aarch64_ext_regno, aarch64_ext_reglane,
aarch64_ext_reglist, aarch64_ext_ldst_reglist,
aarch64_ext_ldst_reglist_r, aarch64_ext_ldst_elemlist,
aarch64_ext_advsimd_imm_shift, aarch64_ext_imm, aarch64_ext_imm_half,
aarch64_ext_advsimd_imm_modified, aarch64_ext_fpimm,
aarch64_ext_imm_rotate1, aarch64_ext_imm_rotate2, aarch64_ext_fbits,
aarch64_ext_aimm, aarch64_ext_limm_1, aarch64_ext_limm, decode_limm,
aarch64_ext_inv_limm, aarch64_ext_ft, aarch64_ext_addr_simple,
aarch64_ext_addr_regoff, aarch64_ext_addr_offset, aarch64_ext_addr_simm,
aarch64_ext_addr_simm10, aarch64_ext_addr_uimm12,
aarch64_ext_simd_addr_post, aarch64_ext_cond, aarch64_ext_sysreg,
aarch64_ext_pstatefield, aarch64_ext_sysins_op, aarch64_ext_barrier,
aarch64_ext_prfop, aarch64_ext_hint, aarch64_ext_reg_extended,
aarch64_ext_reg_shifted, aarch64_ext_sve_addr_ri_s4xvl,
aarch64_ext_sve_addr_ri_s6xvl, aarch64_ext_sve_addr_ri_s9xvl,
aarch64_ext_sve_addr_ri_s4, aarch64_ext_sve_addr_ri_u6,
aarch64_ext_sve_addr_rr_lsl, aarch64_ext_sve_addr_rz_xtw,
aarch64_ext_sve_addr_zi_u5, aarch64_ext_sve_addr_zz,
aarch64_ext_sve_addr_zz_lsl, aarch64_ext_sve_addr_zz_sxtw,
aarch64_ext_sve_addr_zz_uxtw, aarch64_ext_sve_aimm,
aarch64_ext_sve_asimm, aarch64_ext_sve_index, aarch64_ext_sve_limm_mov,
aarch64_ext_sve_quad_index, aarch64_ext_sve_reglist,
aarch64_ext_sve_scale, aarch64_ext_sve_shlimm, aarch64_ext_sve_shrimm,
aarch64_ext_sve_float_half_one, aarch64_ext_sve_float_half_two,
aarch64_ext_sve_float_zero_one, aarch64_opcode_decode): Likewise.
(determine_disassembling_preference, aarch64_decode_insn,
print_insn_aarch64_word, print_insn_data): Take errors struct.
(print_insn_aarch64): Use errors.
* aarch64-asm-2.c: Regenerate.
* aarch64-dis-2.c: Regenerate.
* aarch64-gen.c (print_operand_inserter): Use errors and change type to
boolean in aarch64_insert_operan.
(print_operand_extractor): Likewise.
* aarch64-opc.c (aarch64_print_operand): Use sysreg struct.
With native MIPS/Linux targets the $zero register is inaccessible, with
its supposed context slot provided by the OS occupied by the $restart
register. The PTRACE_GETREGS path takes care of it by artificially
supplying the hardwired contents of $zero in `mips_supply_gregset' or
`mips64_supply_gregset', as applicable, however the PTRACE_PEEKUSER
fallback does not, making the register unavailable, e.g.:
(gdb) info registers
zero at v0 v1 a0 a1 a2 a3
R0 <unavl> 00000001 00000001 d2f1a9fc 00000000 00000000 00417158 00417150
t0 t1 t2 t3 t4 t5 t6 t7
R8 00000004 00000000 fffffff8 00000000 00000000 00000000 00000001 00000007
s0 s1 s2 s3 s4 s5 s6 s7
R16 00000000 00405e30 00000000 00500000 00000000 0052ec08 00000000 00000000
t8 t9 k0 k1 gp sp s8 ra
R24 00000000 00417008 00000000 00000000 0041e220 7fff4ce0 7fff4ce0 00405d0c
status lo hi badvaddr cause pc
<unavl> 00441cf1 00000017 00417004 00800024 00405d10
fcsr fir restart
00800000 00f30000 00000000
(gdb)
or (under certain circumstances):
(gdb) stepi
Register 0 is not available
(gdb)
This is specifically because `mips_linux_register_addr' and
`mips64_linux_register_addr', both correctly return -1 for
MIPS_ZERO_REGNUM, and therefore `linux_nat_trad_target::fetch_registers'
faithfully marks this register as unavailable.
Supply this register artificially then in the PTRACE_PEEKUSER case as
well, correcting this issue.
gdb/
* mips-linux-nat.c (mips_linux_nat_target::fetch_registers):
Supply the MIPS_ZERO_REGNUM register.
Make the `mask_address_var' variable static, it is not used outside
mips-tdep.c and having no target name embedded within it causes a risk
of a namespace clash.
gdb/
* mips-tdep.c (mask_address_var): Make variable static.
Fix a commit f90183d7e3 ("Get GDBserver pid on remote target") bug and
correctly handle the case where the PID of `gdbserver' could not have
been retrieved. If that happens, $server_pid is unset causing:
FAIL: gdb.server/server-kill.exp: p server_pid
ERROR: tcl error sourcing .../gdb/testsuite/gdb.server/server-kill.exp.
ERROR: can't read "server_pid": no such variable
while executing
"if {$server_pid == "" } {
return -1
}"
(file ".../gdb/testsuite/gdb.server/server-kill.exp" line 49)
invoked from within
"source .../gdb/testsuite/gdb.server/server-kill.exp"
("uplevel" body line 1)
invoked from within
"uplevel #0 source .../gdb/testsuite/gdb.server/server-kill.exp"
invoked from within
"catch "uplevel #0 source $test_file_name""
Verify that the variable exists then rather than trying to access it.
gdb/testsuite/
* gdb.server/server-kill.exp: Verify whether `server_pid' exists
rather then trying to access it in determining whether the PID
of `gdbserver' could have been retrieved.
2018-05-15 Christophe Guillon <christophe.guillon@st.com>
* coffcode.h (coff_bigobj_swap_aux_in): Make sure that all fields
of the aux structure are initialised.
Change-Id: I81be255ac6611afbe00995fac550e98e6a07e5df
bfd * targets.c: Wrap nfp_elf64_vec in BFD64 ifdef.
include * opcode/nfp.h: Use uint64_t instead of bfd_vma.
opcodes * nfp-dis.c: Use uint64_t for instruction variables, not bfd_vma.
Also use the correct rel strip-13 variant for more ARM targets.
* testsuite/lib/binutils-common.exp (is_elf_format): Add chorus,
cloudabi, fuchsia, kaos and nto. Merge netbsdelf* into *elf*,
and *uclinux* into *linux*.
* testsuite/binutils-all/objcopy.exp: Accept armeb for rel
strip-13 test, exclude arm-vxworks and arm-windiss.
It turns out that a dwarf2_cu can remain allocated after psymtab
expansion is done, and so it makes sense to clear rust_unions when
done processing it.
Tested on x86-64 Fedora 27.
2018-05-14 Tom Tromey <tom@tromey.com>
* dwarf2read.c (rust_union_quirks): Clear rust_unions.
gas * write.c (maybe_generate_build_notes): Generate notes on a
per-code-section basis. Skip linkonce sections.
ld * testsuite/ld-elf/notes.exp: New file: Run new test.
* testsuite/ld-elf/note1_1.s: New file: Source file for test.
* testsuite/ld-elf/note1_2.s: New file: Source file for test.
* testsuite/ld-elf/note1.r: New file: Expected readelf output.
If IFUNC symbol is defined in position-dependent executable, we should
change it to the normal function and set its address to its PLT entry
which should be resolved by R_*_IRELATIVE at run-time. All external
references should be resolved to its PLT in executable.
bfd/
PR ld/23169
* elf-ifunc.c (_bfd_elf_allocate_ifunc_dyn_relocs): Don't issue
an error on IFUNC pointer defined in PDE.
* elf32-i386.c (elf_i386_finish_dynamic_symbol): Call
_bfd_x86_elf_link_fixup_ifunc_symbol.
* elf64-x86-64.c (elf_x86_64_finish_dynamic_symbol): Likewise.
* elfxx-x86.c (_bfd_x86_elf_link_fixup_ifunc_symbol): New
function.
* elfxx-x86.h (_bfd_x86_elf_link_fixup_ifunc_symbol): New.
ld/
PR ld/23169
* testsuite/ld-ifunc/ifunc-9-i386.d: New file.
* testsuite/ld-ifunc/ifunc-9-x86-64.d: Likewise.
* testsuite/ld-ifunc/pr23169a.c: Likewise.
* testsuite/ld-ifunc/pr23169a.rd: Likewise.
* testsuite/ld-ifunc/pr23169b.c: Likewise.
* testsuite/ld-ifunc/pr23169b.c: Likewise.
* testsuite/ld-ifunc/pr23169c.rd: Likewise.
* testsuite/ld-ifunc/pr23169c.rd: Likewise.
* testsuite/ld-ifunc/ifunc-9-x86.d: Removed.
* testsuite/ld-ifunc/ifunc.exp: Run PR ld/23169 tests.
__bss_start, _end and _edata are defined by linker to mark regions
within executables and shared libraries. All references within
executables should be locally resolved.
This patch doesn't change how their references within shared libraries
are resolved.
bfd/
PR ld/23162
* elfxx-x86.c (elf_x86_linker_defined): New function.
(_bfd_x86_elf_link_check_relocs): Use it to mark __bss_start,
_end and _edata locally defined within executables.
ld/
PR ld/23162
* testsuite/ld-elf/pr23162.map: New file.
* testsuite/ld-elf/pr23162.rd: Likewise.
* testsuite/ld-elf/pr23162a.c: Likewise.
* testsuite/ld-elf/pr23162b.c: Likewise.
* testsuite/ld-elf/shared.exp: Run PR ld/23162 tests.
Rather than just silencing the gcc-8 warnings, I decided to rewrite
the buffer handling in the two functions where gcc was warning.
The rest of the file could do with the same treatment.
* config/tc-score.c (s3_do_macro_bcmp): Don't use fixed size
buffers.
(s3_do_macro_bcmpz): Likewise.
Sections may well belong in multiple segments. The testcase in the PR
saw an allocated section being assigned to an ABIFLAGS segment, then
not being assigned to a LOAD segment because it had already been
handled. To fix that particular problem this patch sets and tests
segment_mark only for LOAD segments. I kept the segment_mark test for
LOAD segments because I think there may otherwise be a problem with
zero size sections.
A few other problems showed up with the testcase. Some targets align
.dynamic, resulting in the test failing with "section .dynamic lma
0x800000c0 adjusted to 0x800000cc" and similar messages. I've tried
to handle that with some more hacks to the segment lma, which do the
right thing for the testcase, but may well fail in other situations.
I've also removed the tests of segment lma (p_paddr) and code involved
in deciding that an adjusted segment no longer covers the file or
program headers. Those test can't be correct in the face of objcopy
--change-section-lma. It may be necessary to reinstate the tests but
do them modulo page size, but we'll see how this goes.
PR 20659
bfd/
* elf.c (rewrite_elf_program_header): Use segment_mark only for
PT_LOAD headers. Delete first_matching_lma and first_suggested_lma.
Instead make matching_lma and suggested_lma pointers to the
sections. Align section vma and lma calculated from segment.
Don't clear includes_phdrs or includes_filehdr based on p_paddr
test. Try to handle alignment padding before first section by
adjusting new segment lma down. Adjust PT_PHDR map p_paddr.
ld/
* testsuite/ld-elf/changelma.d,
* testsuite/ld-elf/changelma.lnk,
* testsuite/ld-elf/changelma.s: New test.
In commit:
commit 8ee22052f6
Author: Andrew Burgess <andrew.burgess@embecosm.com>
Date: Thu May 3 17:46:14 2018 +0100
gdb/x86: Handle kernels using compact xsave format
in two places FXSAVE_ADDR was used instead of FXSAVE_MXCSR_ADDR to get
the address of the mxcsr register within the xsave buffer. This will
mean we are potentially accessing the wrong location within the xsave
buffer.
There are no tests included with this patch. The first mistake would
only trigger an issue if/when the user tries to manually set the mxcsr
register to a value that matches the random (value off stack) value
that is in the xsave buffer, in this case the change by the user will
go unnoticed by GDB, and the default value of mxcsr will be preserved.
The second mistake only happens on the code path where all x87
registers are being written out of the register cache. I'm not sure
how to trigger that code path.
gdb/ChangeLog:
* i387-tdep.c (i387_collect_xsave): Use FXSAVE_MXCSR_ADDR not
FXSAVE_ADDR for the mxcsr register.
gdb_target definitions were removed from configure.tgt in 2007, before
xtensa port was merged. Remove it from the xtensa target as well.
gdb/
2018-05-11 Max Filippov <jcmvbkbc@gmail.com>
* configure.tgt (xtensa*-*-linux*): Drop gdb_target definition.
This gets rid of the core_ops global, and replaces it with
heap-allocated core_target instances. In practice, there will only be
one such instance, though that will change further ahead as more
pieces of multi-target support are merged.
Notice that this replaces one heap-allocated object for another, the
number of allocations is the same. Specifically, currently we
heap-allocate the 'core_data' object, which holds the core's section
table. With this patch, that object is made a field of the
core_target class, and no longer allocated separately.
Note that this bit:
- /* Looks semi-reasonable. Toss the old core file and work on the
- new. */
-
- unpush_target (&core_ops);
does not need a replacement, because by the time we get here, the
target_preopen call at the top of core_target_open has already
unpushed any previous target.
gdb/ChangeLog:
2018-05-11 Pedro Alves <palves@redhat.com>
* corelow.c (core_target) <core_target>: No longer inline.
Initialize m_core_gdbarch, m_core_vec and build the section table
here.
<~core_target>: New.
<core_gdbarch, get_core_register_section>: New methods.
<m_core_section_table, m_core_vec, m_core_gdbarch>: New fields,
factored out from ...
<core_data, core_vec, core_gdbarch>: ... these deleted globals.
(core_ops): Delete.
(sniff_core_bfd): Add gdbarch parameter.
(core_close): Delete, merged into ...
(core_target::close): ... here. Delete self.
(core_close_cleanup): Delete.
(core_target_open): Allocate a core_target on the heap. Use a
unique_ptr instead of a cleanup. Bits moved into the core_target
ctor. Adjust to use core_target methods instead of globals.
(get_core_register_section): Rename to ...
(core_target::get_core_register_section): ... this and adjust.
(struct get_core_registers_cb_data): New.
(get_core_registers_cb): Use it. Use bool.
(core_target::fetch_registers, core_target::files_info)
(core_target::xfer_partial, core_target::read_description)
(core_target::pid_to, core_target::thread_name): Adjust to
reference class fields instead of globals.
* target.h (struct target_ops_deleter, target_ops_up): New.
(previously called 'core_target', but since renamed because
'core_target' is the name of the target_ops class now.)
This eliminates the "the_core_target" global, as preparation for being
able to have more than one core loaded. When we get there, we will
instantiate one core_target object per core instead.
Essentially, this replaces the reference to the_core_target in
core_file_command by a reference to core_bfd, which is per
program_space.
Currently, core_file_command calls 'the_core_target->detach()' even if
the core target is not open and pushed on the target stack. If it is
indeed not open, then the practical effect is that
core_target::detach() prints "No core file now.". That is preserved
by printing that directly from within core_file_command if not
debugging a core.
gdb/ChangeLog:
2018-05-11 Pedro Alves <palves@redhat.com>
* corefile.c (core_file_command): Move to corelow.c.
* corelow.c (the_core_target): Delete.
(core_file_command): Moved from corefile.c. Check exec_bfd
instead of the_core_target. Use target_detach instead of calling
into the_core_target directly.
(maybe_say_no_core_file_now): New.
(core_target::detach): Use it.
(_initialize_corelow): Remove references to the_core_target.
* gdbcore.h (the_core_target): Delete.
This moves the core_bfd global to be a field of the program space. It
then replaces core_bfd with a macro to avoid a massive patch -- the
same approach taken for various other program space fields.
This is a basic transformation for multi-target work.
2018-05-11 Tom Tromey <tromey@redhat.com>
Pedro Alves <tromey@redhat.com>
* corefile.c (core_bfd): Remove.
* gdbcore.h (core_bfd): Now a macro.
* progspace.h (struct program_space) <cbfd>: New field.