xref: /openbmc/qemu/docs/system/gdb.rst (revision 2df1eb27)
1.. _GDB usage:
2
3GDB usage
4---------
5
6QEMU supports working with gdb via gdb's remote-connection facility
7(the "gdbstub"). This allows you to debug guest code in the same
8way that you might with a low-level debug facility like JTAG
9on real hardware. You can stop and start the virtual machine,
10examine state like registers and memory, and set breakpoints and
11watchpoints.
12
13In order to use gdb, launch QEMU with the ``-s`` and ``-S`` options.
14The ``-s`` option will make QEMU listen for an incoming connection
15from gdb on TCP port 1234, and ``-S`` will make QEMU not start the
16guest until you tell it to from gdb. (If you want to specify which
17TCP port to use or to use something other than TCP for the gdbstub
18connection, use the ``-gdb dev`` option instead of ``-s``. See
19`Using unix sockets`_ for an example.)
20
21.. parsed-literal::
22
23   |qemu_system| -s -S -kernel bzImage -hda rootdisk.img -append "root=/dev/hda"
24
25QEMU will launch but will silently wait for gdb to connect.
26
27Then launch gdb on the 'vmlinux' executable::
28
29   > gdb vmlinux
30
31In gdb, connect to QEMU::
32
33   (gdb) target remote localhost:1234
34
35Then you can use gdb normally. For example, type 'c' to launch the
36kernel::
37
38   (gdb) c
39
40Here are some useful tips in order to use gdb on system code:
41
421. Use ``info reg`` to display all the CPU registers.
43
442. Use ``x/10i $eip`` to display the code at the PC position.
45
463. Use ``set architecture i8086`` to dump 16 bit code. Then use
47   ``x/10i $cs*16+$eip`` to dump the code at the PC position.
48
49Breakpoint and Watchpoint support
50=================================
51
52While GDB can always fall back to inserting breakpoints into memory
53(if writable) other features are very much dependent on support of the
54accelerator. For TCG system emulation we advertise an infinite number
55of hardware assisted breakpoints and watchpoints. For other
56accelerators it will depend on if support has been added (see
57supports_guest_debug and related hooks in AccelOpsClass).
58
59As TCG cannot track all memory accesses in user-mode there is no
60support for watchpoints.
61
62Relocating code
63===============
64
65On modern kernels confusion can be caused by code being relocated by
66features such as address space layout randomisation. To avoid
67confusion when debugging such things you either need to update gdb's
68view of where things are in memory or perhaps more trivially disable
69ASLR when booting the system.
70
71Debugging user-space in system emulation
72========================================
73
74While it is technically possible to debug a user-space program running
75inside a system image, it does present challenges. Kernel preemption
76and execution mode changes between kernel and user mode can make it
77hard to follow what's going on. Unless you are specifically trying to
78debug some interaction between kernel and user-space you are better
79off running your guest program with gdb either in the guest or using
80a gdbserver exposed via a port to the outside world.
81
82Debugging multicore machines
83============================
84
85GDB's abstraction for debugging targets with multiple possible
86parallel flows of execution is a two layer one: it supports multiple
87"inferiors", each of which can have multiple "threads". When the QEMU
88machine has more than one CPU, QEMU exposes each CPU cluster as a
89separate "inferior", where each CPU within the cluster is a separate
90"thread". Most QEMU machine types have identical CPUs, so there is a
91single cluster which has all the CPUs in it.  A few machine types are
92heterogeneous and have multiple clusters: for example the ``sifive_u``
93machine has a cluster with one E51 core and a second cluster with four
94U54 cores. Here the E51 is the only thread in the first inferior, and
95the U54 cores are all threads in the second inferior.
96
97When you connect gdb to the gdbstub, it will automatically
98connect to the first inferior; you can display the CPUs in this
99cluster using the gdb ``info thread`` command, and switch between
100them using gdb's usual thread-management commands.
101
102For multi-cluster machines, unfortunately gdb does not by default
103handle multiple inferiors, and so you have to explicitly connect
104to them. First, you must connect with the ``extended-remote``
105protocol, not ``remote``::
106
107    (gdb) target extended-remote localhost:1234
108
109Once connected, gdb will have a single inferior, for the
110first cluster. You need to create inferiors for the other
111clusters and attach to them, like this::
112
113  (gdb) add-inferior
114  Added inferior 2
115  (gdb) inferior 2
116  [Switching to inferior 2 [<null>] (<noexec>)]
117  (gdb) attach 2
118  Attaching to process 2
119  warning: No executable has been specified and target does not support
120  determining executable automatically.  Try using the "file" command.
121  0x00000000 in ?? ()
122
123Once you've done this, ``info threads`` will show CPUs in
124all the clusters you have attached to::
125
126  (gdb) info threads
127    Id   Target Id         Frame
128    1.1  Thread 1.1 (cortex-m33-arm-cpu cpu [running]) 0x00000000 in ?? ()
129  * 2.1  Thread 2.2 (cortex-m33-arm-cpu cpu [halted ]) 0x00000000 in ?? ()
130
131You probably also want to set gdb to ``schedule-multiple`` mode,
132so that when you tell gdb to ``continue`` it resumes all CPUs,
133not just those in the cluster you are currently working on::
134
135  (gdb) set schedule-multiple on
136
137Using unix sockets
138==================
139
140An alternate method for connecting gdb to the QEMU gdbstub is to use
141a unix socket (if supported by your operating system). This is useful when
142running several tests in parallel, or if you do not have a known free TCP
143port (e.g. when running automated tests).
144
145First create a chardev with the appropriate options, then
146instruct the gdbserver to use that device:
147
148.. parsed-literal::
149
150   |qemu_system| -chardev socket,path=/tmp/gdb-socket,server=on,wait=off,id=gdb0 -gdb chardev:gdb0 -S ...
151
152Start gdb as before, but this time connect using the path to
153the socket::
154
155   (gdb) target remote /tmp/gdb-socket
156
157Note that to use a unix socket for the connection you will need
158gdb version 9.0 or newer.
159
160Advanced debugging options
161==========================
162
163Changing single-stepping behaviour
164^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
165
166The default single stepping behavior is step with the IRQs and timer
167service routines off. It is set this way because when gdb executes a
168single step it expects to advance beyond the current instruction. With
169the IRQs and timer service routines on, a single step might jump into
170the one of the interrupt or exception vectors instead of executing the
171current instruction. This means you may hit the same breakpoint a number
172of times before executing the instruction gdb wants to have executed.
173Because there are rare circumstances where you want to single step into
174an interrupt vector the behavior can be controlled from GDB. There are
175three commands you can query and set the single step behavior:
176
177``maintenance packet qqemu.sstepbits``
178   This will display the MASK bits used to control the single stepping
179   IE:
180
181   ::
182
183      (gdb) maintenance packet qqemu.sstepbits
184      sending: "qqemu.sstepbits"
185      received: "ENABLE=1,NOIRQ=2,NOTIMER=4"
186
187``maintenance packet qqemu.sstep``
188   This will display the current value of the mask used when single
189   stepping IE:
190
191   ::
192
193      (gdb) maintenance packet qqemu.sstep
194      sending: "qqemu.sstep"
195      received: "0x7"
196
197``maintenance packet Qqemu.sstep=HEX_VALUE``
198   This will change the single step mask, so if wanted to enable IRQs on
199   the single step, but not timers, you would use:
200
201   ::
202
203      (gdb) maintenance packet Qqemu.sstep=0x5
204      sending: "qemu.sstep=0x5"
205      received: "OK"
206
207Examining physical memory
208^^^^^^^^^^^^^^^^^^^^^^^^^
209
210Another feature that QEMU gdbstub provides is to toggle the memory GDB
211works with, by default GDB will show the current process memory respecting
212the virtual address translation.
213
214If you want to examine/change the physical memory you can set the gdbstub
215to work with the physical memory rather with the virtual one.
216
217The memory mode can be checked by sending the following command:
218
219``maintenance packet qqemu.PhyMemMode``
220    This will return either 0 or 1, 1 indicates you are currently in the
221    physical memory mode.
222
223``maintenance packet Qqemu.PhyMemMode:1``
224    This will change the memory mode to physical memory.
225
226``maintenance packet Qqemu.PhyMemMode:0``
227    This will change it back to normal memory mode.
228
229Security considerations
230=======================
231
232Connecting to the GDB socket allows running arbitrary code inside the guest;
233in case of the TCG emulation, which is not considered a security boundary, this
234also means running arbitrary code on the host. Additionally, when debugging
235qemu-user, it allows directly downloading any file readable by QEMU from the
236host.
237
238The GDB socket is not protected by authentication, authorization or encryption.
239It is therefore a responsibility of the user to make sure that only authorized
240clients can connect to it, e.g., by using a unix socket with proper
241permissions, or by opening a TCP socket only on interfaces that are not
242reachable by potential attackers.
243