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[[!meta copyright="Copyright © 2007, 2008, 2009, 2011, 2012, 2013, 2014, 2016
Free Software Foundation, Inc."]]

[[!meta license="""[[!toggle id="license" text="GFDL 1.2+"]][[!toggleable
id="license" text="Permission is granted to copy, distribute and/or modify this
document under the terms of the GNU Free Documentation License, Version 1.2 or
any later version published by the Free Software Foundation; with no Invariant
Sections, no Front-Cover Texts, and no Back-Cover Texts.  A copy of the license
is included in the section entitled [[GNU Free Documentation
License|/fdl]]."]]"""]]

Here are some hints to debug with GNU Mach.

[[!toc levels=2]]


# Kernel Debugger (KDB)

Mach has a built-in kernel debugger.
[Manual](http://www.gnu.org/software/hurd/gnumach-doc/Kernel-Debugger.html).

First, make sure to enable it. Either by using a pre-packaged gnumach-image-something-dbg, or by passing --enable-kdb to the ./configure invocation.

Then, reproduce the issue again. If something like a kernel trap happens, you will end up in the GNU Mach debugger. Otherwise, type control-alt-d to make Mach enter it by hand.

If you are running in kvm or qemu, it is convenient to use the curses frontend to be able to copy/paste.

To get the register values, type

    show registers

To get a backtrace, type

    trace
    
, which will print both function return addresses and function parameters, such as

    0x107cf1(8088488,5e,40000008,2aa008,0)
    0x1071bc(0,0,0,0,0)
    0x106831(24fe00,2000,b,800,0)

Run the addr2line tool on the return addresses:

    $ addr2line -i -f -e /boot/gnumach 0x107cf1 0x1071bc 0x106831

This will print the source code lines of the backtrace.

To get the userland backtrace of the thread, you can use

    trace/u

To examine the backtrace of some given thread, use

    show all thread/u

to get the whole listing of all tasks and threads.  You can then use trace/t or trace/tu to trace a specific thread.  gcc however uses the frame pointer as a normal register unless `-fno-omit-frame-pointer` is given.  It can thus be useful to rebuild glibc with that option, by adding `extra_cflags = -fno-omit-frame-pointer` in `glibc/debian/sysdeps/hurd-i386.mk`

To examine a variable, use nm /boot/gnumach to get the address of the variable (e.g. 0x123400), and use

    x 0x123400

to read it. One can also write to it by using

    w 0x123400

Another interesting feature is watching a variable, by using

    watch 0x123400

and then type continue, to let Mach continue execution. The debugger will be entered again on any change in that variable. The watch is implemented in hardware, so it does not disturb or slow down execution at all.  The same can be achieved programmatically, e.g. using


    struct db_watchpoint watch = { .task = NULL, .loaddr= 0x40e, .hiaddr = 0x40e+2, .link = NULL};
    db_set_hw_watchpoint(&watch, 0);

To discover what an arbitrary address points to, try

    whatis  0x123400

# GDB in QEMU

When you're [[running_a_system_in_QEMU|hurd/running/qemu]] you can directly
[use GDB on the running
kernel](https://www.qemu.org/docs/master/system/gdb.html).

When debugggin 32-bit gnumach, you can specify the kernel file in the
command line with the `-kernel` option and the boot modules with
`-initrd`, as described in [[hurd/running/qemu]].  This however does
not work for 64-bit gnumach, due to a [limitation in
qemu](https://gitlab.com/qemu-project/qemu/-/issues/243).  To overcome
this, you can either patch qemu to enable multiboot also for 64-bit
ELF, or build a bootable ISO image with `grub-mkrescue`.

To enable the gdbserver on a running instance, you need to access the
qemu monitor and use the `gdbserver` command. For example, with
libvirt/virt-manager

    $ virsh --connect qemu:///session qemu-monitor-command --domain hurd --hmp --cmd gdbserver

Otherwise, if you start qemu manually, you can use the `-s` and `-S`
shortcuts, that will open a tcp connection on port 1234 and wait for
gdb to attach before starting the vm.

If you don't need a graphical interface, e.g. you're working on the
boot process, you could use stdio as an emulated serial port with
`-nographic`, and append `console=com0` to the kernel command line,
either in grub or with the `-append` option.

Once qemu has started, you can connect to the gdbserver with

    $ gdb gnumach
    ...
    (gdb) target remote :1234
    (gdb) c

You can also automate some steps with a `.gdbinit` file in your
working directory. For example:

    set print pretty
    target remote :1234
    # let's set some breakpoints
    b Panic
    b c_boot_entry
    b user_bootstrap
    b ../i386/intel/pmap.c:1981
    # we can also refer to virtual addresses in userspace
    b *0x804901d
    # this shows the instruction being executed
    display/i $pc
    layout asm


## [[open_issues/debugging_gnumach_startup_qemu_gdb]]

## Debug 64-bit gnumach

[[build|microkernel/mach/gnumach/building/]] 64-bit gnumach with:

    $ export CFLAGS=-g
    $ ../configure --enable-kdb ...

run a spare Hurd vm (prepare for data loss in vm):

* `kvm -net user,hostfwd=tcp:127.0.0.1:2222-:22 -net nic,model=e1000 -drive file=$(echo debian-hurd*.img),cache=writeback -m 1G`
* `cd gnumach/build`
* `scp -P 2222 gnumach.gz user@127.0.0.1:/home/user/`
* You may copy `gnumach.gz` (also create new grub entry) or replace using `mv /home/user/gnumach.gz /boot/gnumach-xxx.gz`
* Shutdown vm.
* Append `console=com0` in boot menu and switch to console mode in qemu. (We have known issues with vga output for 64-bit.)
* You may load only required modules for debugging.
* `kvm -s -S -net user,hostfwd=tcp:127.0.0.1:2222-:22 -net nic,model=e1000 -drive file=$(echo debian-hurd*.img),cache=writeback -m 1G` (note: `-s -S` added.)
* `gdb ./gnumach`
* `(gdb) target remote :1234`
* Press `c` to continue booting.


example `/boot/grub/grub.cfg`:

    multiboot       /boot/gnumach-1.8-486.gz root=part:2:device:hd0 console=com0
    ...
    echo            'Loading the Hurd ...'
    module          /hurd/ext2fs.static ext2fs --readonly \
                    --multiboot-command-line='${kernel-command-line}' \
                     \
                    --host-priv-port='${host-port}' --device-master-port='${device-port}' \
                    --exec-server-task='${exec-task}' -T typed '${root}' \
                    '$(fs-task=task-create)' '$(task-resume)'
    module          /lib/ld.so.1 exec /hurd/exec '$(exec-task=task-create)'




# Code Inside the Kernel

Alternatively you can use an approach like this one: add the following code
snippet to `device/ds_routines.c`'s `ds_device_open` function, right at the top
of the function, and modify the code as needed.

      void D (char *s)
      {
        switch (s[0] - '0')
          {
          case 0:
           printf ("Hello from %s!\n", __FUNCTION__);
           break;
          case 1:
           printf ("%s: Invoking task_collect_scan.\n", __FUNCTION__);
           extern void task_collect_scan (void);
           task_collect_scan ();
           break;
          default:
           printf ("No idea what you want me to do.\n");
           break;
          }
      }
    
      if (name && name[0] == 'D')
        D (name + 1);

Then boot your system and do something like this:

    # devprobe D0
    Hello from D!
    # devprobe D1
    D: Invoking task_collect_scan.
    # devprobe D2
    No idea what you want me to do.

This is especially useful if you need to manually trigger some stuff inside the
running kernel, as with the *D1* example.


## Writing to the Screen Buffer

If you're doing real low level debugging, you might want to put variations of
the following snipped into the code, this code will write a `#` character at
line `[LINE]`, column `[COLUMN]` on the screen:

    *((char *) 0xb8000 + 2 * ([LINE] * 80 + [COLUMN])) = '#';
    halt_cpu ();

The call of `halt_cpu` will -- as the name suggests -- halt the system
afterwards.  This might be what you want or it might not, but it is needed at
some place when running the kernel inside QEMU, as QEMU somehow decides not to
update its display buffer anymore under certain conditions.


# Halting the CPU and Examining Registers

## IRC, freenode, #hurd, 2011-07-14

    <braunr> one ugly trick i use when printf isn't available is to halt the
      cpu
    <braunr> then use info registers to know where the cpu is halted
    <braunr> and you'll know if you reached that code or not
    <braunr> (info registers is a qemu command)


# Serial Console

## IRC, freenode, #hurd, 2011-11-13

    <youpi> use console=com0
    <youpi> to activate the console on the first serial port


# `ud2` instruction

## IRC, freenode, #hurd, 2013-10-31

    [master-x86_64]
    <phcoder> GNU Mach 1.3.99
    <phcoder> Running on xen-3.0-x86_64.
    <phcoder> AT386 boot: physical memory from 0x0 to 0x40000000
    <youpi> \o/
    <phcoder> well when loaded through pvgrub2 i hangs without any message
    <phcoder> any pointers on debugging?
    <youpi> I usually put the ud2 instruction along the path to see where it
      crashes