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646d754d14
This commit builds on the previous series of commits to share the
target description caching code between GDB and gdbserver for
x86/Linux targets.
The objective of this commit is to move the four functions (2 each of)
i386_linux_read_description and amd64_linux_read_description into the
gdb/arch/ directory and combine them so we have just a single copy of
each. Then GDB, gdbserver, and the in-process-agent (IPA) will link
against these shared functions.
One curiosity with this patch is the function
x86_linux_post_init_tdesc. On the gdbserver side the two functions
amd64_linux_read_description and i386_linux_read_description have some
functionality that is not present on the GDB side, there is some
additional configuration that is performed as each target description
is created, to setup the expedited registers.
To support this I've added the function x86_linux_post_init_tdesc.
This function is called from the two *_linux_read_description
functions, but is implemented separately for GDB and gdbserver.
An alternative approach that avoids adding x86_linux_post_init_tdesc
would be to have x86_linux_tdesc_for_tid return a non-const target
description, then in x86_target::low_arch_setup we could inspect the
target description to figure out if it is 64-bit or not, and modify
the target description as needed. In the end I think that adding the
x86_linux_post_init_tdesc function is the simpler solution.
The contents of gdbserver/linux-x86-low.cc have moved to
gdb/arch/x86-linux-tdesc-features.c, and gdbserver/linux-x86-tdesc.h
has moved to gdb/arch/x86-linux-tdesc-features.h, this change leads to
some updates in the #includes in the gdbserver/ directory.
This commit also changes how target descriptions are cached.
Previously both GDB and gdbserver used static C-style arrays to act as
the tdesc cache. This was fine, except for two problems. Either the
C-style arrays would need to be placed in x86-linux-tdesc-features.c,
which would allow us to use the x86_linux_*_tdesc_count_1() functions
to size the arrays for us, or we'd need to hard code the array sizes
using separate #defines, which we'd then have to keep in sync with the
rest of the code in x86-linux-tdesc-features.c.
Given both of these problems I decided a better solution would be to
just switch to using a std::unordered_map to act as the cache. This
will resize automatically, and we can use the xcr0 value as the key.
At first inspection, using xcr0 might seem to be a problem; after all
the {i386,amd64}_create_target_description functions take more than
just the xcr0 value. However, this patch is only for x86/Linux
targets, and for x86/Linux all of the other flags passed to the tdesc
creation functions have constant values and so are irrelevant when we
consider tdesc caching.
For testing I've done the following:
- Built on x86-64 GNU/Linux for all targets, and just for the native
target,
- Build on i386 GNU/Linux for all targets, and just for the native
target,
- Build on a 64-bit, non-x86 GNU/Linux for all targets, just for the
native target, and for targets x86_64-*-linux and i386-*-linux.
Approved-By: Felix Willgerodt <felix.willgerodt@intel.com>
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| .. | ||
| .dir-locals.el | ||
| .gitattributes | ||
| .gitignore | ||
| acinclude.m4 | ||
| aclocal.m4 | ||
| ax-result-types.def | ||
| ax.cc | ||
| ax.h | ||
| ChangeLog-2002-2021 | ||
| config.in | ||
| configure | ||
| configure.ac | ||
| configure.srv | ||
| debug.cc | ||
| debug.h | ||
| dll.cc | ||
| dll.h | ||
| fork-child.cc | ||
| gdb_proc_service.h | ||
| gdbreplay.cc | ||
| gdbthread.h | ||
| hostio.cc | ||
| hostio.h | ||
| i387-fp.cc | ||
| i387-fp.h | ||
| inferiors.cc | ||
| inferiors.h | ||
| linux-aarch32-low.cc | ||
| linux-aarch32-low.h | ||
| linux-aarch32-tdesc.cc | ||
| linux-aarch32-tdesc.h | ||
| linux-aarch64-ipa.cc | ||
| linux-aarch64-low.cc | ||
| linux-aarch64-tdesc.cc | ||
| linux-aarch64-tdesc.h | ||
| linux-amd64-ipa.cc | ||
| linux-arc-low.cc | ||
| linux-arm-low.cc | ||
| linux-arm-tdesc.cc | ||
| linux-arm-tdesc.h | ||
| linux-csky-low.cc | ||
| linux-i386-ipa.cc | ||
| linux-ia64-low.cc | ||
| linux-loongarch-low.cc | ||
| linux-low.cc | ||
| linux-low.h | ||
| linux-m68k-low.cc | ||
| linux-mips-low.cc | ||
| linux-nios2-low.cc | ||
| linux-or1k-low.cc | ||
| linux-ppc-ipa.cc | ||
| linux-ppc-low.cc | ||
| linux-ppc-tdesc-init.h | ||
| linux-riscv-low.cc | ||
| linux-s390-ipa.cc | ||
| linux-s390-low.cc | ||
| linux-s390-tdesc.h | ||
| linux-sh-low.cc | ||
| linux-sparc-low.cc | ||
| linux-tic6x-low.cc | ||
| linux-x86-low.cc | ||
| linux-x86-tdesc.cc | ||
| linux-xtensa-low.cc | ||
| Makefile.in | ||
| mem-break.cc | ||
| mem-break.h | ||
| netbsd-aarch64-low.cc | ||
| netbsd-amd64-low.cc | ||
| netbsd-i386-low.cc | ||
| netbsd-low.cc | ||
| netbsd-low.h | ||
| notif.cc | ||
| notif.h | ||
| proc-service.cc | ||
| proc-service.list | ||
| README | ||
| regcache.cc | ||
| regcache.h | ||
| remote-utils.cc | ||
| remote-utils.h | ||
| server.cc | ||
| server.h | ||
| symbol.cc | ||
| target.cc | ||
| target.h | ||
| tdesc.cc | ||
| tdesc.h | ||
| thread-db.cc | ||
| tracepoint.cc | ||
| tracepoint.h | ||
| utils.cc | ||
| utils.h | ||
| win32-i386-low.cc | ||
| win32-low.cc | ||
| win32-low.h | ||
| x86-low.cc | ||
| x86-low.h | ||
| x86-tdesc.h | ||
| xtensa-xtregs.cc | ||
README for GDBserver & GDBreplay
by Stu Grossman and Fred Fish
Introduction:
This is GDBserver, a remote server for Un*x-like systems. It can be used to
control the execution of a program on a target system from a GDB on a different
host. GDB and GDBserver communicate using the standard remote serial protocol.
They communicate via either a serial line or a TCP connection.
For more information about GDBserver, see the GDB manual:
https://sourceware.org/gdb/current/onlinedocs/gdb/Remote-Protocol.html
Usage (server (target) side):
First, you need to have a copy of the program you want to debug put onto
the target system. The program can be stripped to save space if needed, as
GDBserver doesn't care about symbols. All symbol handling is taken care of by
the GDB running on the host system.
To use the server, you log on to the target system, and run the `gdbserver'
program. You must tell it (a) how to communicate with GDB, (b) the name of
your program, and (c) its arguments. The general syntax is:
target> gdbserver COMM PROGRAM [ARGS ...]
For example, using a serial port, you might say:
target> gdbserver /dev/com1 emacs foo.txt
This tells GDBserver to debug emacs with an argument of foo.txt, and to
communicate with GDB via /dev/com1. GDBserver now waits patiently for the
host GDB to communicate with it.
To use a TCP connection, you could say:
target> gdbserver host:2345 emacs foo.txt
This says pretty much the same thing as the last example, except that we are
going to communicate with the host GDB via TCP. The `host:2345' argument means
that we are expecting to see a TCP connection to local TCP port 2345.
(Currently, the `host' part is ignored.) You can choose any number you want for
the port number as long as it does not conflict with any existing TCP ports on
the target system. This same port number must be used in the host GDB's
`target remote' command, which will be described shortly. Note that if you chose
a port number that conflicts with another service, GDBserver will print an error
message and exit.
On some targets, GDBserver can also attach to running programs. This is
accomplished via the --attach argument. The syntax is:
target> gdbserver --attach COMM PID
PID is the process ID of a currently running process. It isn't necessary
to point GDBserver at a binary for the running process.
Usage (host side):
You need an unstripped copy of the target program on your host system, since
GDB needs to examine it's symbol tables and such. Start up GDB as you normally
would, with the target program as the first argument. (You may need to use the
--baud option if the serial line is running at anything except 9600 baud.)
Ie: `gdb TARGET-PROG', or `gdb --baud BAUD TARGET-PROG'. After that, the only
new command you need to know about is `target remote'. It's argument is either
a device name (usually a serial device, like `/dev/ttyb'), or a HOST:PORT
descriptor. For example:
(gdb) target remote /dev/ttyb
communicates with the server via serial line /dev/ttyb, and:
(gdb) target remote the-target:2345
communicates via a TCP connection to port 2345 on host `the-target', where
you previously started up GDBserver with the same port number. Note that for
TCP connections, you must start up GDBserver prior to using the `target remote'
command, otherwise you may get an error that looks something like
`Connection refused'.
Building GDBserver:
See the `configure.srv` file for the list of host triplets you can build
GDBserver for.
Building GDBserver for your host is very straightforward. If you build
GDB natively on a host which GDBserver supports, it will be built
automatically when you build GDB. You can also build just GDBserver:
% mkdir obj
% cd obj
% path-to-toplevel-sources/configure --disable-gdb
% make all-gdbserver
(If you have a combined binutils+gdb tree, you may want to also
disable other directories when configuring, e.g., binutils, gas, gold,
gprof, and ld.)
If you prefer to cross-compile to your target, then you can also build
GDBserver that way. For example:
% export CC=your-cross-compiler
% path-to-topevel-sources/configure --disable-gdb
% make all-gdbserver
Using GDBreplay:
A special hacked down version of GDBserver can be used to replay remote
debug log files created by GDB. Before using the GDB "target" command to
initiate a remote debug session, use "set remotelogfile <filename>" to tell
GDB that you want to make a recording of the serial or tcp session. Note
that when replaying the session, GDB communicates with GDBreplay via tcp,
regardless of whether the original session was via a serial link or tcp.
Once you are done with the remote debug session, start GDBreplay and
tell it the name of the log file and the host and port number that GDB
should connect to (typically the same as the host running GDB):
$ gdbreplay logfile host:port
Then start GDB (preferably in a different screen or window) and use the
"target" command to connect to GDBreplay:
(gdb) target remote host:port
Repeat the same sequence of user commands to GDB that you gave in the
original debug session. GDB should not be able to tell that it is talking
to GDBreplay rather than a real target, all other things being equal. Note
that GDBreplay echos the command lines to stderr, as well as the contents of
the packets it sends and receives. The last command echoed by GDBreplay is
the next command that needs to be typed to GDB to continue the session in
sync with the original session.