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Now that defs.h, server.h and common-defs.h are included via the
`-include` option, it is no longer necessary for source files to include
them. Remove all the inclusions of these files I could find. Update
the generation scripts where relevant.
Change-Id: Ia026cff269c1b7ae7386dd3619bc9bb6a5332837
Approved-By: Pedro Alves <pedro@palves.net>
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This commit is the result of the following actions:
- Running gdb/copyright.py to update all of the copyright headers to
include 2024,
- Manually updating a few files the copyright.py script told me to
update, these files had copyright headers embedded within the
file,
- Regenerating gdbsupport/Makefile.in to refresh it's copyright
date,
- Using grep to find other files that still mentioned 2023. If
these files were updated last year from 2022 to 2023 then I've
updated them this year to 2024.
I'm sure I've probably missed some dates. Feel free to fix them up as
you spot them.
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Replace spaces with tabs in a bunch of places.
Change-Id: If0f87180f1d13028dc178e5a8af7882a067868b0
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This commit is the result of running the gdb/copyright.py script,
which automated the update of the copyright year range for all
source files managed by the GDB project to be updated to include
year 2023.
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This commit brings all the changes made by running gdb/copyright.py
as per GDB's Start of New Year Procedure.
For the avoidance of doubt, all changes in this commits were
performed by the script.
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Use the current target description to include CSRs into the RISC-V
baremetal core dumps.
Every CSR declared in the current target description will be included
in the core dump.
It will be critical for users that they have the same target
description in use when loading the core file as was in use when
writing the core file. This should be fine if the user allows the
target description to be written into the core file.
In more detail, this commit adds a NT_RISCV_CSR note type. The
contents of this section is a series of either 4-byte (on RV32
targets), or 8-byte (on RV64 targets) values. Every CSR that is
mentioned in the current target description is written out in the
order the registers appear in the target description. As a
consequence it is critical that the exact same target description,
including the same register order, is in use when the CSRs are loaded
from the core file.
gdb/ChangeLog:
* riscv-none-tdep.c: Add 'user-regs.h' and 'target-description.h'
includes.
(riscv_csrset): New static global.
(riscv_update_csrmap): New function.
(riscv_iterate_over_regset_sections): Process CSRs.
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This commit adds the ability for bare metal RISC-V target to generate
core files from within GDB.
The intended use case is that a user will connect to a remote bare
metal target, debug up to some error condition, then generate a core
file in the normal way using:
(gdb) generate-core-file
This core file can then be used to revisit the state of the remote
target without having to reconnect to the remote target.
The core file creation code is split between two new files. In
elf-none-tdep.c is code for any architecture with the none
ABI (i.e. bare metal) when the BFD library is built with ELF support.
In riscv-none-tdep.c are the RISC-V specific parts. This is where the
regset and regcache_map_entry structures are defined that control how
registers are laid out in the core file. As this file could (in
theory at least) be used for a non-ELF bare metal RISC-V target, the
calls into elf-none-tdep.c are guarded with '#ifdef HAVE_ELF'.
Currently for RISC-V only the x-regs and f-regs (if present) are
written out. In future commits I plan to add support for writing out
the RISC-V CSRs.
The core dump format is based around generating an ELF containing
sections for the writable regions of memory that a user could be
using. Which regions are dumped rely on GDB's existing common core
dumping code, GDB will attempt to figure out the stack and heap as
well as copying out writable data sections as identified by the
original ELF.
Register information is added to the core dump using notes, just as it
is for Linux of FreeBSD core dumps. The note types used consist of
the 3 basic types you would expect in a OS based core dump,
NT_PRPSINFO, NT_PRSTATUS, NT_FPREGSET.
The layout of these notes differs slightly (due to field sizes)
between RV32 and RV64. Below I describe the data layout for each
note. In all cases, all padding fields should be set to zero.
Note NT_PRPSINFO is optional. Its data layout is:
struct prpsinfo32_t /* For RV32. */
{
uint8_t padding[32];
char fname[16];
char psargs[80];
}
struct prpsinfo64_t /* For RV64. */
{
uint8_t padding[40];
char fname[16];
char psargs[80];
}
Field 'fname' - null terminated string consisting of the basename of
(up to the fist 15 characters of) the executable. Any additional
space should be set to zero. If there's no executable name then
this field can be set to all zero.
Field 'psargs' - a null terminated string up to 80 characters in
length. Any additional space should be filled with zero. This
field contains the full executable path and any arguments passed
to the executable. If there's nothing sensible to write in this
field then fill it with zero.
Note NT_PRSTATUS is required, its data layout is:
struct prstatus32_t /* For RV32. */
{
uint8_t padding_1[12];
uint16_t sig;
uint8_t padding_2[10];
uint32_t thread_id;
uint8_t padding_3[44];
uint32_t x_regs[32];
uint8_t padding_4[4];
}
struct prstatus64_t /* For RV64. */
{
uint8_t padding_1[12];
uint16_t sig;
uint8_t padding_2[18];
uint32_t thread_id;
uint8_t padding_3[76];
uint64_t x_regs[32];
uint8_t padding_4[4];
}
Field 'sig' - the signal that stopped this thread. It's implementation
defined what this field actually means. Within GDB this will be
the signal number that the remote target reports as the stop
reason for this thread.
Field 'thread_is' - the thread id for this thread. It's implementation
defined what this field actually means. Within GDB this will be
thread thread-id that is assigned to each remote thread.
Field 'x_regs' - at index 0 we store the program counter, and at
indices 1 to 31 we store x-registers 1 to 31. x-register 0 is not
stored, its value is always zero anyway.
Note NT_FPREGSET is optional, its data layout is:
fpregset32_t /* For targets with 'F' extension. */
{
uint32_t f_regs[32];
uint32_t fcsr;
}
fpregset64_t /* For targets with 'D' extension . */
{
uint64_t f_regs[32];
uint32_t fcsr;
}
Field 'f_regs' - stores f-registers 0 to 31.
Field 'fcsr' - stores the fcsr CSR register, and is always 4-bytes.
The rules for ordering the notes is the same as for Linux. The
NT_PRSTATUS note must come before any other notes about additional
register sets. And for multi-threaded targets all registers for a
single thread should be grouped together. This is because only
NT_PRSTATUS includes a thread-id, all additional register notes after
a NT_PRSTATUS are assumed to belong to the same thread until a
different NT_PRSTATUS is seen.
gdb/ChangeLog:
* Makefile.in (ALL_TARGET_OBS): Add riscv-none-tdep.o.
(ALLDEPFILES): Add riscv-none-tdep.c.
* configure: Regenerate.
* configure.ac (CONFIG_OBS): Add elf-none-tdep.o when BFD has ELF
support.
* configure.tgt (riscv*-*-*): Include riscv-none-tdep.c.
* elf-none-tdep.c: New file.
* elf-none-tdep.h: New file.
* riscv-none-tdep.c: New file.
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