xref: /openbmc/qemu/docs/system/introduction.rst (revision 39920a04)
1Introduction
2============
3
4Virtualisation Accelerators
5---------------------------
6
7QEMU's system emulation provides a virtual model of a machine (CPU,
8memory and emulated devices) to run a guest OS. It supports a number
9of hypervisors (known as accelerators) as well as a JIT known as the
10Tiny Code Generator (TCG) capable of emulating many CPUs.
11
12.. list-table:: Supported Accelerators
13  :header-rows: 1
14
15  * - Accelerator
16    - Host OS
17    - Host Architectures
18  * - KVM
19    - Linux
20    - Arm (64 bit only), MIPS, PPC, RISC-V, s390x, x86
21  * - Xen
22    - Linux (as dom0)
23    - Arm, x86
24  * - Intel HAXM (hax)
25    - Linux, Windows
26    - x86
27  * - Hypervisor Framework (hvf)
28    - MacOS
29    - x86 (64 bit only), Arm (64 bit only)
30  * - Windows Hypervisor Platform (whpx)
31    - Windows
32    - x86
33  * - NetBSD Virtual Machine Monitor (nvmm)
34    - NetBSD
35    - x86
36  * - Tiny Code Generator (tcg)
37    - Linux, other POSIX, Windows, MacOS
38    - Arm, x86, Loongarch64, MIPS, PPC, s390x, Sparc64
39
40Feature Overview
41----------------
42
43System emulation provides a wide range of device models to emulate
44various hardware components you may want to add to your machine. This
45includes a wide number of VirtIO devices which are specifically tuned
46for efficient operation under virtualisation. Some of the device
47emulation can be offloaded from the main QEMU process using either
48vhost-user (for VirtIO) or :ref:`Multi-process QEMU`. If the platform
49supports it QEMU also supports directly passing devices through to
50guest VMs to eliminate the device emulation overhead. See
51:ref:`device-emulation` for more details.
52
53There is a full :ref:`featured block layer<Live Block Operations>`
54which allows for construction of complex storage topology which can be
55stacked across multiple layers supporting redirection, networking,
56snapshots and migration support.
57
58The flexible ``chardev`` system allows for handling IO from character
59like devices using stdio, files, unix sockets and TCP networking.
60
61QEMU provides a number of management interfaces including a line based
62:ref:`Human Monitor Protocol (HMP)<QEMU monitor>` that allows you to
63dynamically add and remove devices as well as introspect the system
64state. The :ref:`QEMU Monitor Protocol<QMP Ref>` (QMP) is a well
65defined, versioned, machine usable API that presents a rich interface
66to other tools to create, control and manage Virtual Machines. This is
67the interface used by higher level tools interfaces such as `Virt
68Manager <https://virt-manager.org/>`_ using the `libvirt framework
69<https://libvirt.org>`_.
70
71For the common accelerators QEMU, supported debugging with its
72:ref:`gdbstub<GDB usage>` which allows users to connect GDB and debug
73system software images.
74
75Running
76-------
77
78QEMU provides a rich and complex API which can be overwhelming to
79understand. While some architectures can boot something with just a
80disk image, those examples elide a lot of details with defaults that
81may not be optimal for modern systems.
82
83For a non-x86 system where we emulate a broad range of machine types,
84the command lines are generally more explicit in defining the machine
85and boot behaviour. You will find often find example command lines in
86the :ref:`system-targets-ref` section of the manual.
87
88While the project doesn't want to discourage users from using the
89command line to launch VMs, we do want to highlight that there are a
90number of projects dedicated to providing a more user friendly
91experience. Those built around the ``libvirt`` framework can make use
92of feature probing to build modern VM images tailored to run on the
93hardware you have.
94
95That said, the general form of a QEMU command line can be expressed
96as:
97
98.. parsed-literal::
99
100  $ |qemu_system| [machine opts] \\
101                  [cpu opts] \\
102                  [accelerator opts] \\
103                  [device opts] \\
104                  [backend opts] \\
105                  [interface opts] \\
106                  [boot opts]
107
108Most options will generate some help information. So for example:
109
110.. parsed-literal::
111
112   $ |qemu_system| -M help
113
114will list the machine types supported by that QEMU binary. ``help``
115can also be passed as an argument to another option. For example:
116
117.. parsed-literal::
118
119  $ |qemu_system| -device scsi-hd,help
120
121will list the arguments and their default values of additional options
122that can control the behaviour of the ``scsi-hd`` device.
123
124.. list-table:: Options Overview
125  :header-rows: 1
126  :widths: 10, 90
127
128  * - Options
129    -
130  * - Machine
131    - Define the machine type, amount of memory etc
132  * - CPU
133    - Type and number/topology of vCPUs. Most accelerators offer
134      a ``host`` cpu option which simply passes through your host CPU
135      configuration without filtering out any features.
136  * - Accelerator
137    - This will depend on the hypervisor you run. Note that the
138      default is TCG, which is purely emulated, so you must specify an
139      accelerator type to take advantage of hardware virtualization.
140  * - Devices
141    - Additional devices that are not defined by default with the
142      machine type.
143  * - Backends
144    - Backends are how QEMU deals with the guest's data, for example
145      how a block device is stored, how network devices see the
146      network or how a serial device is directed to the outside world.
147  * - Interfaces
148    - How the system is displayed, how it is managed and controlled or
149      debugged.
150  * - Boot
151    - How the system boots, via firmware or direct kernel boot.
152
153In the following example we first define a ``virt`` machine which is a
154general purpose platform for running Aarch64 guests. We enable
155virtualisation so we can use KVM inside the emulated guest. As the
156``virt`` machine comes with some built in pflash devices we give them
157names so we can override the defaults later.
158
159.. code::
160
161 $ qemu-system-aarch64 \
162    -machine type=virt,virtualization=on,pflash0=rom,pflash1=efivars \
163    -m 4096 \
164
165We then define the 4 vCPUs using the ``max`` option which gives us all
166the Arm features QEMU is capable of emulating. We enable a more
167emulation friendly implementation of Arm's pointer authentication
168algorithm. We explicitly specify TCG acceleration even though QEMU
169would default to it anyway.
170
171.. code::
172
173 -cpu max,pauth-impdef=on \
174 -smp 4 \
175 -accel tcg \
176
177As the ``virt`` platform doesn't have any default network or storage
178devices we need to define them. We give them ids so we can link them
179with the backend later on.
180
181.. code::
182
183 -device virtio-net-pci,netdev=unet \
184 -device virtio-scsi-pci \
185 -device scsi-hd,drive=hd \
186
187We connect the user-mode networking to our network device. As
188user-mode networking isn't directly accessible from the outside world
189we forward localhost port 2222 to the ssh port on the guest.
190
191.. code::
192
193 -netdev user,id=unet,hostfwd=tcp::2222-:22 \
194
195We connect the guest visible block device to an LVM partition we have
196set aside for our guest.
197
198.. code::
199
200 -blockdev driver=raw,node-name=hd,file.driver=host_device,file.filename=/dev/lvm-disk/debian-bullseye-arm64 \
201
202We then tell QEMU to multiplex the :ref:`QEMU monitor` with the serial
203port output (we can switch between the two using :ref:`keys in the
204character backend multiplexer`). As there is no default graphical
205device we disable the display as we can work entirely in the terminal.
206
207.. code::
208
209 -serial mon:stdio \
210 -display none \
211
212Finally we override the default firmware to ensure we have some
213storage for EFI to persist its configuration. That firmware is
214responsible for finding the disk, booting grub and eventually running
215our system.
216
217.. code::
218
219 -blockdev node-name=rom,driver=file,filename=(pwd)/pc-bios/edk2-aarch64-code.fd,read-only=true \
220 -blockdev node-name=efivars,driver=file,filename=$HOME/images/qemu-arm64-efivars
221