DWARF sections have special names on AIX which need be handled
by objdump in order to correctly print them.
This patch also adds the correlation in bfd for future uses.
bfd/
* libxcoff.h (struct xcoff_dwsect_name): Add DWARF name.
* coff-rs6000.c (xcoff_dwsect_names): Update.
* coffcode.h (sec_to_styp_flags): Likewise.
(coff_new_section_hook): Likewise.
binutils/
* dwarf.h (struct dwarf_section): Add XCOFF name.
* dwarf.c (struct dwarf_section_display): Update.
* objdump.c (load_debug_section): Add XCOFF name handler.
(dump_dwarf_section): Likewise.
gas/
* config/tc-ppc.c (ppc_change_debug_section): Update to
match new name's field.
Since gcc commit, 3c70b3ca1ef58f302bf8c16d9e7c7bb8626408bf, we now enable
elf attributes for all riscv targets by default in gcc. Therefore, I
think binutils should have the same behavior, in case users are writing
assembly files. If --enable-default-riscv-attribute isn't set, then we
enable the elf attributes for all riscv targets by default.
ChangLog:
binutils/
* testsuite/binutils-all/readelf.s: Add comments for riscv.
* testsuite/binutils-all/readelf.s-64: Likewise.
* testsuite/binutils-all/readelf.s-64-unused: Likewise.
* testsuite/binutils-all/readelf.ss: Likewise.
* testsuite/binutils-all/readelf.ss-64: Likewise.
* testsuite/binutils-all/readelf.ss-64-unused: Likewise.
gas/
* configure.ac: If --enable-default-riscv-attribute isn't set,
then we enable the elf attributes for all riscv targets by
default.
* configure: Regenerated.
We shouldn't be asserting on anything to do with leb128 values, or
reporting file and line numbers when something unexpected happens.
leb128 data is of indeterminate length, perfect for fuzzer mayhem.
It would only make sense to assert or report dwarf.c/readelf.c source
lines if the code had already sized and sanity checked the leb128
values.
After removing the assertions, the testcase then gave:
<37> DW_AT_discr_list : 5 byte block: 0 0 0 0 0 (label 0, label 0, label 0, label 0, <corrupt>
readelf: Warning: corrupt discr_list - unrecognized discriminant byte 0x5
<3d> DW_AT_encoding : 0 (void)
<3e> DW_AT_identifier_case: 0 (case_sensitive)
<3f> DW_AT_virtuality : 0 (none)
<40> DW_AT_decimal_sign: 5 (trailing separate)
So the DW_AT_discr_list was showing more data than just the 5 byte
block. That happened due to "end" pointing a long way past the end of
block, and uvalue decrementing past zero on one of the leb128 bytes.
PR 28069
* dwarf.c (display_discr_list): Remove assertions. Delete "end"
parameter, use initial "data" pointer as the end. Formatting.
Don't count down bytes as they are read.
(read_and_display_attr_value): Adjust display_discr_list call.
(read_and_print_leb128): Don't pass __FILE__ and __LINE__ to
report_leb_status.
* dwarf.h (report_leb_status): Don't report file and line
numbers. Delete file and lnum parameters,
(READ_ULEB, READ_SLEB): Adjust.
Add GNU_PROPERTY_1_NEEDED:
#define GNU_PROPERTY_1_NEEDED GNU_PROPERTY_UINT32_OR_LO
to indicate the needed properties by the object file.
Add GNU_PROPERTY_1_NEEDED_INDIRECT_EXTERN_ACCESS:
#define GNU_PROPERTY_1_NEEDED_INDIRECT_EXTERN_ACCESS (1U << 0)
to indicate that the object file requires canonical function pointers and
cannot be used with copy relocation.
binutils/
* readelf.c (decode_1_needed): New.
(print_gnu_property_note): Handle GNU_PROPERTY_1_NEEDED.
include/
* elf/common.h (GNU_PROPERTY_1_NEEDED): New.
(GNU_PROPERTY_1_NEEDED_INDIRECT_EXTERN_ACCESS): Likewise.
ld/
* testsuite/ld-elf/property-1_needed-1a.d: New file.
* testsuite/ld-elf/property-1_needed-1.s: Likewise.
binutils currently fails to compile on Solaris 10:
/vol/src/gnu/binutils/hg/binutils-2.37-branch/git/bfd/opncls.c: In function 'bfd_get_debug_link_info_1':
/vol/src/gnu/binutils/hg/binutils-2.37-branch/git/bfd/opncls.c:1231:16: error: implicit declaration of function 'strnlen' [-Werror=implicit-function-declaration]
1231 | crc_offset = strnlen (name, size) + 1;
| ^~~~~~~
/vol/src/gnu/binutils/hg/binutils-2.37-branch/git/bfd/opncls.c:1231:16: error: incompatible implicit declaration of built-in function 'strnlen' [-Werror]
/vol/src/gnu/binutils/hg/binutils-2.37-branch/git/bfd/opncls.c: In function 'bfd_get_alt_debug_link_info':
/vol/src/gnu/binutils/hg/binutils-2.37-branch/git/bfd/opncls.c:1319:20: error: incompatible implicit declaration of built-in function 'strnlen' [-Werror]
1319 | buildid_offset = strnlen (name, size) + 1;
| ^~~~~~~
and in a couple of other places. The platform lacks strnlen, and while
libiberty.h can provide a fallback declaration, the necessary configure
test isn't run.
Fixed with the following patch. Tested on i386-pc-solaris2.10.
2021-07-06 Rainer Orth <ro@CeBiTec.Uni-Bielefeld.DE>
bfd:
* configure.ac: Check for strnlen declaration.
* configure, config.in: Regenerate.
binutils:
* configure.ac: Check for strnlen declaration.
* configure, config.in: Regenerate.
DW_FORM_ref1, DW_FORM_ref2, DW_FORM_ref4, DW_FORM_ref1, and
DW_FORM_ref_udata are all supposed to be within the containing unit.
PR 28047
* dwarf.c (get_type_abbrev_from_form): Add cu_end parameter.
Check DW_FORM_ref1 etc. arg against cu_end rather than end of
section. Adjust all callers.
* readelf.c (process_archive): Reset file position to the
beginning when calling process_object for thin archive members.
* testsuite/binutils-all/readelf.exp: Add test.
* testsuite/binutils-all/readelf.h.thin: New file.
In function 'strncpy',
inlined from 'display_debug_lines_decoded' at /home/alan/src/binutils-gdb/binutils/dwarf.c:5434:5,
inlined from 'display_debug_lines' at /home/alan/src/binutils-gdb/binutils/dwarf.c:5567:21:
/usr/include/bits/string_fortified.h:95:10: error: '__builtin_strncpy' specified bound 36 equals destination size [-Werror=stringop-truncation]
No need for strncpy here, the string being copied always fits the
destination buffer.
* dwarf.c (display_debug_lines_decoded): Use memcpy rather than
strncpy when trimming file name length to MAX_FILENAME_LENGTH.
Don't make an unnecessary copy when length is good.
Implement GNU_PROPERTY_UINT32_AND_XXX/GNU_PROPERTY_UINT32_OR_XXX:
https://sourceware.org/pipermail/gnu-gabi/2021q1/000467.html
1. GNU_PROPERTY_UINT32_AND_LO..GNU_PROPERTY_UINT32_AND_HI
#define GNU_PROPERTY_UINT32_AND_LO 0xb0000000
#define GNU_PROPERTY_UINT32_AND_HI 0xb0007fff
A bit in the output pr_data field is set only if it is set in all
relocatable input pr_data fields. If all bits in the the output
pr_data field are zero, this property should be removed from output.
If the bit is 1, all input relocatables have the feature. If the
bit is 0 or the property is missing, the info is unknown.
2. GNU_PROPERTY_UINT32_OR_LO..GNU_PROPERTY_UINT32_OR_HI
#define GNU_PROPERTY_UINT32_OR_LO 0xb0008000
#define GNU_PROPERTY_UINT32_OR_HI 0xb000ffff
A bit in the output pr_data field is set if it is set in any
relocatable input pr_data fields. If all bits in the the output
pr_data field are zero, this property should be removed from output.
If the bit is 1, some input relocatables have the feature. If the
bit is 0 or the property is missing, the info is unknown.
bfd/
* elf-properties.c (_bfd_elf_parse_gnu_properties): Handle
GNU_PROPERTY_UINT32_AND_LO, GNU_PROPERTY_UINT32_AND_HI,
GNU_PROPERTY_UINT32_OR_LO and GNU_PROPERTY_UINT32_OR_HI.
(elf_merge_gnu_properties): Likewise.
binutils/
* readelf.c (print_gnu_property_note): Handle
GNU_PROPERTY_UINT32_AND_LO, GNU_PROPERTY_UINT32_AND_HI,
GNU_PROPERTY_UINT32_OR_LO and GNU_PROPERTY_UINT32_OR_HI.
include/
* elf/common.h (GNU_PROPERTY_UINT32_AND_LO): New.
(GNU_PROPERTY_UINT32_AND_HI): Likewise.
(GNU_PROPERTY_UINT32_OR_LO): Likewise.
(GNU_PROPERTY_UINT32_OR_HI): Likewise.
ld/
* testsuite/ld-elf/property-and-1.d: New file.
* testsuite/ld-elf/property-and-1.s: Likewise.
* testsuite/ld-elf/property-and-2.d: Likewise.
* testsuite/ld-elf/property-and-2.s: Likewise.
* testsuite/ld-elf/property-and-3.d: Likewise.
* testsuite/ld-elf/property-and-3.s: Likewise.
* testsuite/ld-elf/property-and-4.d: Likewise.
* testsuite/ld-elf/property-and-empty.s: Likewise.
* testsuite/ld-elf/property-or-1.d: Likewise.
* testsuite/ld-elf/property-or-1.s: Likewise.
* testsuite/ld-elf/property-or-2.d: Likewise.
* testsuite/ld-elf/property-or-2.s: Likewise.
* testsuite/ld-elf/property-or-3.d: Likewise.
* testsuite/ld-elf/property-or-3.s: Likewise.
* testsuite/ld-elf/property-or-4.d: Likewise.
* testsuite/ld-elf/property-or-empty.s: Likewise.
I finally found time to teach readelf to identify PIEs in the file
header display and program header display. So in place of
"DYN (Shared object file)" which isn't completely true, show
"DYN (Position-Independent Executable file)".
It requires a little bit of untangling code in readelf due to
process_program_headers setting up dynamic_addr and dynamic_size,
needed to scan .dynamic for the DT_FLAGS_1 entry, and
process_program_headers itself wanting to display the file type in
some cases. At first I modified process_program_header using a
"probe" parameter similar to get_section_headers in order to inhibit
output, but decided it was cleaner to separate out
locate_dynamic_sections.
binutils/
* readelf.c (locate_dynamic_section, is_pie): New functions.
(get_file_type): Replace e_type parameter with filedata. Call
is_pie for ET_DYN. Update all callers.
(process_program_headers): Use local variables dynamic_addr and
dynamic_size, updating filedata on exit from function. Set
dynamic_size of 1 to indicate no dynamic section or segment.
Update tests of dynamic_size throughout.
* testsuite/binutils-all/x86-64/pr27708.dump: Update expected output.
ld/
* testsuite/ld-pie/vaddr-0.d: Update expected output.
gdb/
* testsuite/lib/gdb.exp (exec_is_pie): Match new PIE readelf output.
If you look at the type used for implicit_const objects in binutils/dwarf.c,
you'll get sometimes bfd_signed_vma and sometimes dwarf_signed_vma.
They are the same on 64-bit hosts, but not on 32-bit hosts, and the latter
discrepancy, in particular in process_abbrev_set, is responsible for the
following error issued by objdump on some object files containing DWARF 5:
binutils/dwarf.c:1108: read LEB value is too large to store in destination
variable
binutis/
* dwarf.c (struct abbrev_attr): Change type of implicit_const.
(add_abbrev_attr): Likewise.
(process_abbrev_set): Likewise.
(display_debug_abbrev): Adjust to above change.
Fix commit 4de91c10cd, which cached the single section header read
to pick up file header extension fields. Also, testing e_shoff in
get_section_headers opened a hole for fuzzers where we'd end up with
segfaults due to non-zero e_shnum but NULL section_headers.
* readelf.c (get_section_headers): Don't test e_shoff here, leave
that to get_32bit_section_headers or get_64bit_section_headers.
(process_object): Throw away section header read to print file
header extension.
A number of filedata entries were not cleared. Make sure they are
all cleared out, except the ones needed for archive handling.
* readelf.c (struct filedata): Move archive_file_offset and
archive_file_size earlier.
(free_filedata): Clear using memset.
This is a followup to git commit 8ff66993e0, a patch aimed at
segfaults found invoking readelf multiple times with fuzzed objects.
In that patch I added code to clear more stashed data early in
process_section_headers, along with any stashed section headers. This
patch instead relies on clearing out the stash at the end of
process_object, making sure that process_object doesn't exit early.
The patch also introduces some new wrapper functions.
* readelf.c (GET_ELF_SYMBOLS): Delete. Replace with..
(get_elf_symbols): ..this new function throughout.
(get_32bit_section_headers): Don't free section_headers.
(get_64bit_section_headers): Likewise.
(get_section_headers): New function, use throughout in place of
32bit and 64bit variants.
(get_dynamic_section): Similarly.
(process_section_headers): Don't free filedata memory here.
(get_file_header): Don't get section headers here..
(process_object): ..Read them here instead. Don't exit without
freeing filedata memory.
Older gcc reports:
.../bfd/dwarf2.c: In function 'read_ranges':
.../bfd/dwarf2.c:3107: error: comparison between signed and unsigned
.../bfd/dwarf2.c: In function 'read_rnglists':
.../bfd/dwarf2.c:3189: error: comparison between signed and unsigned
Similarly for binutils/dwarf.c. Arrange for the left sides of the > to
also be unsigned quantities.
Splitting up help strings makes it more likely that at least some of
the help translation survives adding new options.
* readelf.c (parse_args): Call dwarf_select_sections_all on
--debug-dump without optarg.
(usage): Associate -w and --debug-dump options closely.
Split up help message. Remove extraneous blank lines around
ctf help.
* objdump.c (usage): Similarly.
The CP0 control register set has never been defined, however encodings
for the CFC0 and CTC0 instructions remained available for implementers
up until the MIPS32 ISA declared them invalid and causing the Reserved
Instruction exception[1]. Therefore we handle them for both assembly
and disassembly, however in the latter case the names of CP0 registers
from the regular set are incorrectly printed if named registers are
requested. This is because we do not define separate operand classes
for coprocessor regular and control registers respectively, which means
the disassembler has no way to tell the two cases apart. Consequently
nonsensical disassembly is produced like:
cfc0 v0,c0_random
Later the MIPSr5 ISA reused the encodings for XPA ASE MFHC0 and MTHC0
instructions[2] although it failed to document them in the relevant
opcode table until MIPSr6 only.
Correct the issue then by defining a new register class, OP_REG_CONTROL,
and corresponding operand codes, `g' and `y' for the two positions in
the machine instruction a control register operand can take. Adjust the
test cases affected accordingly.
While at it swap the regular MIPS opcode table "cfc0" and "ctc0" entries
with each other so that they come in the alphabetical order.
References:
[1] "MIPS32 Architecture For Programmers, Volume II: The MIPS32
Instruction Set", MIPS Technologies, Inc., Document Number: MD00086,
Revision 1.00, August 29, 2002, Table A-9 "MIPS32 COP0 Encoding of
rs Field", p. 242
[2] "MIPS Architecture For Programmers, Volume II-A: The MIPS32
Instruction Set", MIPS Technologies, Inc., Document Number: MD00086,
Revision 5.04, December 11, 2013, Section 3.2 "Alphabetical List of
Instructions", pp. 195, 216
include/
* opcode/mips.h: Document `g' and `y' operand codes.
(mips_reg_operand_type): Add OP_REG_CONTROL enumeration
constant.
gas/
* tc-mips.c (convert_reg_type) <OP_REG_CONTROL>: New case.
(macro) <M_TRUNCWS, M_TRUNCWD>: Use the `g' rather than `G'
operand code.
opcodes/
* mips-dis.c (print_reg) <OP_REG_COPRO>: Move control register
handling code over to...
<OP_REG_CONTROL>: ... this new case.
* mips-opc.c (decode_mips_operand) <'g', 'y'>: New cases.
(mips_builtin_opcodes): Update "cfc1", "ctc1", "cttc1", "cttc2",
"cfc0", "ctc0", "cfc2", "ctc2", "cfc3", and "ctc3" entries
replacing the `G' operand code with `g'. Update "cftc1" and
"cftc2" entries replacing the `E' operand code with `y'.
* micromips-opc.c (decode_micromips_operand) <'g'>: New case.
(micromips_opcodes): Update "cfc1", "cfc2", "ctc1", and "ctc2"
entries replacing the `G' operand code with `g'.
binutils/
* testsuite/binutils-all/mips/mips-xpa-virt-1.d: Correct CFC0
operand disassembly.
* testsuite/binutils-all/mips/mips-xpa-virt-3.d: Likewise.
Fix commit 9785fc2a4d ("MIPS: Fix XPA base and Virtualization ASE
instruction handling") and explicitly use the `mips:3000' machine for
disassembly across the XPA base and XPA Virtualization ASE test cases,
providing actual coverage for the `virt' and `xpa' disassembler options
and removing failures for targets that default to those ASEs enabled:
mipsisa32r2-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r2-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r2-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r2-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r2-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r2-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r2el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r2el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r2el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r2el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r2el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r2el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r3-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r3-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r3-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r3-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r3-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r3-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r3el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r3el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r3el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r3el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r3el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r3el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r5-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r5-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r5-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r5-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r5-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r5-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r5el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r5el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r5el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r5el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r5el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r5el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r6-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r6-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r6-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r6-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r6-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r6-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r6el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r6el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r6el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa32r6el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa32r6el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa32r6el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r2-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r2-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r2-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r2-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r2-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r2-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r2el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r2el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r2el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r2el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r2el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r2el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r3-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r3-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r3-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r3-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r3-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r3-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r3el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r3el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r3el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r3el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r3el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r3el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r5-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r5-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r5-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r5-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r5-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r5-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r5el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r5el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r5el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r5el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r5el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r5el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r6-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r6-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r6-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r6-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r6-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r6-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r6el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r6el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r6el-elf -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
mipsisa64r6el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 1
mipsisa64r6el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 2
mipsisa64r6el-linux -FAIL: MIPS XPA and Virtualization ASE instruction disassembly 3
This is because the test cases rely on these ASEs being disabled for
disassembly by default and expect instructions belonging to these ASEs
not to be shown unless explicitly enabled. The `mips-xpa-virt-4' test
case passes regardless, but we want it to verify the explicit options do
work, so use the `mips:3000' machine to set the defaults there as well.
binutils/
* testsuite/binutils-all/mips/mips-xpa-virt-1.d: Use `mips:3000'
machine for disassembly.
* testsuite/binutils-all/mips/mips-xpa-virt-2.d: Likewise.
* testsuite/binutils-all/mips/mips-xpa-virt-3.d: Likewise.
* testsuite/binutils-all/mips/mips-xpa-virt-4.d: Likewise.
commit a7664973b2
Author: Jan Beulich <jbeulich@suse.com>
Date: Mon Apr 26 10:41:35 2021 +0200
x86: correct overflow checking for 16-bit PC-relative relocs
caused linker failure when building 16-bit program in a 32-bit ELF
container. Update GNU_PROPERTY_X86_FEATURE_2_USED with
#define GNU_PROPERTY_X86_FEATURE_2_CODE16 (1U << 12)
to indicate that 16-bit mode instructions are used in the input object:
https://groups.google.com/g/x86-64-abi/c/UvvXWeHIGMA
to indicate that 16-bit mode instructions are used in the object to
allow linker to properly perform relocation overflow check for 16-bit
PC-relative relocations in 16-bit mode instructions.
1. Update x86 assembler to always generate the GNU property note with
GNU_PROPERTY_X86_FEATURE_2_CODE16 for .code16 in ELF object.
2. Update i386 and x86-64 linkers to use 16-bit PC16 relocations if
input object is marked with GNU_PROPERTY_X86_FEATURE_2_CODE16.
bfd/
PR ld/27905
* elf32-i386.c: Include "libiberty.h".
(elf_howto_table): Add 16-bit R_386_PC16 entry.
(elf_i386_rtype_to_howto): Add a BFD argument. Use 16-bit
R_386_PC16 if input has 16-bit mode instructions.
(elf_i386_info_to_howto_rel): Update elf_i386_rtype_to_howto
call.
(elf_i386_tls_transition): Likewise.
(elf_i386_relocate_section): Likewise.
* elf64-x86-64.c (x86_64_elf_howto_table): Add 16-bit
R_X86_64_PC16 entry.
(elf_x86_64_rtype_to_howto): Use 16-bit R_X86_64_PC16 if input
has 16-bit mode instructions.
* elfxx-x86.c (_bfd_x86_elf_parse_gnu_properties): Set
elf_x86_has_code16 if relocatable input is marked with
GNU_PROPERTY_X86_FEATURE_2_CODE16.
* elfxx-x86.h (elf_x86_obj_tdata): Add has_code16.
(elf_x86_has_code16): New.
binutils/
PR ld/27905
* readelf.c (decode_x86_feature_2): Support
GNU_PROPERTY_X86_FEATURE_2_CODE16.
gas/
PR ld/27905
* config/tc-i386.c (set_code_flag): Update x86_feature_2_used
with GNU_PROPERTY_X86_FEATURE_2_CODE16 for .code16 in ELF
object.
(set_16bit_gcc_code_flag): Likewise.
(x86_cleanup): Always generate the GNU property note if
x86_feature_2_used isn't 0.
* testsuite/gas/i386/code16-2.d: New file.
* testsuite/gas/i386/code16-2.s: Likewise.
* testsuite/gas/i386/x86-64-code16-2.d: Likewise.
* testsuite/gas/i386/i386.exp: Run code16-2 and x86-64-code16-2.
include/
PR ld/27905
* elf/common.h (GNU_PROPERTY_X86_FEATURE_2_CODE16): New.
ld/
PR ld/27905
* testsuite/ld-i386/code16.d: New file.
* testsuite/ld-i386/code16.t: Likewise.
* testsuite/ld-x86-64/code16.d: Likewise.
* testsuite/ld-x86-64/code16.t: Likewise.
* testsuite/ld-i386/i386.exp: Run code16.
* testsuite/ld-x86-64/x86-64.exp: Likewise.
The official name for Loongson Architecture is LoongArch, it is better
to use LoongArch instead of Loongson Loongarch for EM_LOONGARCH to avoid
confusion and keep consistent with the various of software in the future.
The official documentation in Chinese:
http://www.loongson.cn/uploadfile/cpu/LoongArch.pdf
The translated version in English:
https://loongson.github.io/LoongArch-Documentation/
binutils/
* readelf.c (get_machine_name): Change Loongson Loongarch to
LoongArch.
include/
* elf/common.h (EM_LOONGARCH): Change Loongson Loongarch to
LoongArch.
PR 27884
* dwarf.c (get_type_abbrev_from_form): Replace cu_offset_return
param with map_return, and return map for DW_FORM_ref_addr.
(get_type_signedness): Adjust calls to get_type_abbrev_from_form.
Pass returned cu map start and end to recursive call.
(read_and_display_attr_value): Similarly.
* dwarf.c (display_debug_names): Complain when header length is
too small. Avoid pointer UB. Sanity check augmentation string,
CU table, TU table and foreign TU table sizes.
* dwarf.c (display_debug_frames): Delete initial_length_size.
Avoid pointer UB. Constrain data reads to length given in header.
Sanity check cie header length. Only skip up to next FDE on
finding augmentation data too long.
* dwarf.c (display_debug_ranges): Delete initial_length_size.
Correct fallback size calculated on finding a reloc. Constrain
data reads to length given in header. Avoid pointer UB.
