TranslateProject/sources/tech/20220916 Using Python and NetworkManager to control the network.md

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[#]: subject: "Using Python and NetworkManager to control the network"
[#]: via: "https://fedoramagazine.org/using-python-and-networkmanager-to-control-the-network/"
[#]: author: "Beniamino Galvani https://fedoramagazine.org/author/bengal/"
[#]: collector: "lkxed"
[#]: translator: " "
[#]: reviewer: " "
[#]: publisher: " "
[#]: url: " "
Using Python and NetworkManager to control the network
======
![][1]
Photo by [Taylor Vick][2] on [Unsplash][3]
[NetworkManager][4] is the default network management service on Fedora and several other Linux distributions. Its main purpose is to take care of things like setting up interfaces, adding addresses and routes to them and configuring other network related aspects of the system, such as DNS.
There are other tools that offer similar functionality. However one of the advantages of NetworkManager is that it offers a powerful API. Using this API, other applications can inspect, monitor and change the networking state of the system.
This article first introduces the API of NetworkManager and presents how to use it from a Python program. In the second part it shows some practical examples: how to connect to a wireless network or to add an IP address to an interface programmatically via NetworkManager.
### The API
NetworkManager provides a D-Bus API.[D-Bus][5] is a message bus system that allows processes to talk to each other; using D-Bus, a process that wants to offer some services can register on the bus with a well-known name (for example, “org.freedesktop.NetworkManager”) and expose some objects, each identified by a path. Using *d-feet*, a graphical tool to inspect D-Bus objects, we can see the object tree exposed by the NetworkManager service:
![][6]
Each object has properties, methods and signals, grouped into different interfaces. For example, the following is a simplified view of the interfaces for the second device object:
![][7]
We see that there are different interfaces; the *org.freedesktop.NetworkManager.Device* interface contains some properties common to all devices, like the state, the MTU and IP configurations. Since this device is Ethernet, it also has a *org.freedesktop.NetworkManager.Device.Wired* D-Bus interface containing other properties such as the link speed.
The full documentation for the [D-Bus API of NetworkManager is here.][8]
A client can connect to the NetworkManager service using the well-known name and perform operations on the exposed objects. For example, it can invoke methods, access properties or receive notifications via signals. In this way, it can control almost every aspect of network configuration. In fact, all the tools that interact with NetworkManager nmcli, nmtui, GNOME control center, the KDE applet, Cockpit use this API.
### libnm
When developing a program, it can be convenient to automatically instantiate objects from the objects available on D-Bus and keep their properties synchronized; or to be able to have method calls on those objects automatically dispatched to the corresponding D-Bus method. Such objects are usually called *proxies* and are used to hide the complexity of D-Bus communication from the developer.
For this purpose, the NetworkManager project provides a library called **libnm**, written in C and based on GNOMEs GLib and GObject. The library provides C language bindings for functionality provided by NetworkManager. Being a GLib library, it is usable from other languages as well via GObject introspection, as explained below.
The library maps fairly closely to the D-Bus API of NetworkManager. It wraps remote D-Bus objects as native GObjects, and D-Bus signals and properties to GObject signals and properties. Furthermore, it provides helpful accessors and utility functions.
### Overview of libnm objects
The diagram below shows the most important objects in libnm and their relationship:
![][9]
*NMClient* caches all the objects instantiated from D-Bus. The object is typically created at the beginning at the program and provides a way to access other objects.
A *NMDevice* represents a network interface, physical (as Ethernet, Infiniband, Wi-Fi, etc.) or virtual (as a bridge or a IP tunnel). Each device type supported by NetworkManager has a dedicated subclass that implements type-specific properties and methods. For example, a[NMDeviceWifi][10] has properties related to the wireless configuration and to access points found during the scan, while a[NMDeviceVlan][11] has properties describing its VLAN-id and the parent device.
*NMClient* also provides a list of *NMRemoteConnection* objects. *NMRemoteConnection* is one of the two implementations of the *NMConnection* interface. A *connection* (or *connection profile*) contains all the configuration needed to connect to a specific network.
The difference between a *NMRemoteConnection* and a *NMSimpleConnection* is that the former is a proxy for a connection existing on D-Bus while the latter is not. In particular, *NMSimpleConnection* can be instantiated when a new blank connection object is required. This is useful for, example, when adding a new connection to NetworkManager.
The last object in the diagram is *NMActiveConnection*. This represents an active connection to a specific network using settings from a *NMRemoteConnection*.
### GObject introspection
[GObject introspection][12] is a layer that acts as a bridge between a C library using GObject and programming language runtimes such as JavaScript, Python, Perl, Java, Lua, .NET, Scheme, etc.
When the library is built, sources are scanned to generate introspection metadata describing, in a language-agnostic way, all the constants, types, functions, signals, etc. exported by the library. The resulting metadata is used to automatically generate bindings to call into the C library from other languages.
One form of metadata is a GObject Introspection Repository (GIR) XML file. GIRs are mostly used by languages that generate bindings at compile time. The GIR can be translated into a machine-readable format called Typelib that is optimized for fast access and lower memory footprint; for this reason it is mostly used by languages that generate bindings at runtime.
[This page][13] lists all the introspection bindings for other languages. For a Python example we will use [PyGObject][14] which is included in the *python3-gobject* RPM on Fedora.
### A basic example
Lets start with a simple Python program that prints information about the system:
```
import gi
gi.require_version("NM", "1.0")
from gi.repository import GLib, NM
client = NM.Client.new(None)
print("version:", client.get_version())
```
At the beginning we import the introspection module and then the Glib and NM modules. Since there could be multiple versions of the NM module in the system, we make certain to load the right one. Then we create a client object and print the version of NetworkManager.
Next, we want to get a list of devices and print some of their properties:
```
devices = client.get_devices()
print("devices:")
for device in devices:
print(" - name:", device.get_iface());
print(" type:", device.get_type_description())
print(" state:", device.get_state().value_nick)
```
The device state is an enum of type *NMDeviceState* and we use value_nick to get its description. The output is something like:
```
version: 1.41.0
devices:
- name: lo
type: loopback
state: unmanaged
- name: enp1s0
type: ethernet
state: activated
- name: wlp4s0
type: wifi
state: activated
```
In the libnm documentation we see that the[NMDevice][15] object has a get_ip4_config() method which returns a NMIPConfig object and provides access to addresses, routes and other parameters currently set on the device. We can print them with:
```
ip4 = device.get_ip4_config()
if ip4 is not None:
print(" addresses:")
for a in ip4.get_addresses():
print(" - {}/{}".format(a.get_address(),
a.get_prefix()))
print(" routes:")
for r in ip4.get_routes():
print(" - {}/{} via {}".format(r.get_dest(),
r.get_prefix(),
r.get_next_hop()))
```
From this, the output for enp1s0 becomes:
```
- name: enp1s0
type: ethernet
state: activated
addresses:
- 192.168.122.191/24
- 172.26.1.1/16
routes:
- 172.26.0.0/16 via None
- 192.168.122.0/24 via None
- 0.0.0.0/0 via 192.168.122.1
```
### Connecting to a Wi-Fi network
Now that we have mastered the basics, lets try something more advanced. Suppose we are in the range of a wireless network and we want to connect to it.
As mentioned before, a connection profile describes all the settings required to connect to a specific network. Conceptually, well need to perform two different operations: first insert a new connection profile into NetworkManagers configuration and second activate it. Fortunately, the API provides method [nm_client_add_and_activate_connection_async()][16] that does everything in a single step. When calling the method we need to pass at least the following parameters:
* the NMConnection we want to add, containing all the needed properties;
* the device to activate the connection on;
* the callback function to invoke when the method completes asynchronously.
We can construct the connection with:
```
def create_connection():
connection = NM.SimpleConnection.new()
ssid = GLib.Bytes.new("Home".encode("utf-8"))
s_con = NM.SettingConnection.new()
s_con.set_property(NM.SETTING_CONNECTION_ID,
"my-wifi-connection")
s_con.set_property(NM.SETTING_CONNECTION_TYPE,
"802-11-wireless")
s_wifi = NM.SettingWireless.new()
s_wifi.set_property(NM.SETTING_WIRELESS_SSID, ssid)
s_wifi.set_property(NM.SETTING_WIRELESS_MODE,
"infrastructure")
s_wsec = NM.SettingWirelessSecurity.new()
s_wsec.set_property(NM.SETTING_WIRELESS_SECURITY_KEY_MGMT,
"wpa-psk")
s_wsec.set_property(NM.SETTING_WIRELESS_SECURITY_PSK,
"z!q9at#0b1")
s_ip4 = NM.SettingIP4Config.new()
s_ip4.set_property(NM.SETTING_IP_CONFIG_METHOD, "auto")
s_ip6 = NM.SettingIP6Config.new()
s_ip6.set_property(NM.SETTING_IP_CONFIG_METHOD, "auto")
connection.add_setting(s_con)
connection.add_setting(s_wifi)
connection.add_setting(s_wsec)
connection.add_setting(s_ip4)
connection.add_setting(s_ip6)
return connection
```
The function creates a new *NMSimpleConnection* and sets all the needed properties. All the properties are grouped into *settings*. In particular, the *NMSettingConnection* setting contains general properties such as the profile name and its type. *NMSettingWireless* indicates the wireless network name (SSID) and that we want to operate in “infrastructure” mode, that is, as a wireless client. The wireless security setting specifies the authentication mechanism and a password. We set both IPv4 and IPv6 to “auto” so that the interface gets addresses via DHCP and IPv6 autoconfiguration.
All the properties supported by NetworkManager are described in the *nm-settings* man page and in the “Connection and Setting API Reference”[section][17] of the libnm documentation.
To find a suitable interface, we loop through all devices on the system and return the first Wi-Fi device.
```
def find_wifi_device(client):
for device in client.get_devices():
if device.get_device_type() == NM.DeviceType.WIFI:
return device
return None
```
What is missing now is a callback function, but its easier if we look at it later. We can proceed invoking the add_and_activate_connection_async() method:
```
import gi
gi.require_version("NM", "1.0")
from gi.repository import GLib, NM
# other functions here...
main_loop = GLib.MainLoop()
client = NM.Client.new(None)
connection = create_connection()
device = find_wifi_device(client)
client.add_and_activate_connection_async(
connection, device, None, None, add_and_activate_cb, None
)
main_loop.run()
```
To support multiple asynchronous operations without blocking execution of the whole program, libnm uses an[event loop][18] mechanism. For an introduction to event loops in GLib see [this tutorial][19]. The call to main_loop.run() waits until there are events (such as the callback for our method invocation, or any update from D-Bus). Event processing continues until the main loop is explicitly terminated. This happens in the callback:
```
def add_and_activate_cb(client, result, data):
try:
ac = client.add_and_activate_connection_finish(result)
print("ActiveConnection {}".format(ac.get_path()))
print("State {}".format(ac.get_state().value_nick))
except Exception as e:
print("Error:", e)
main_loop.quit()
```
Here, we use client.add_and_activate_connection_finish() to get the result for the asynchronous method. The result is a *NMActiveConnection* object and we print its D-Bus path and state.
Note that the callback is invoked as soon as the active connection is created. It may still be attempting to connect. In other words, when the callback runs we dont have a guarantee that the activation completed successfully. If we want to ensure that, we would need to monitor the active connection state until it changes to *activated* (or to *deactivated* in case of failure). In this example, we just print that the activation started, or why it failed, and then we quit the main loop; after that, the main_loop.run() call will end and our program will terminate.
### Adding an address to a device
Once there is a connection active on a device, we might decide that we want to configure an additional IP address on it.
There are different ways to do that. One way would be to modify the profile and activate it again similar to what we saw in the previous example. Another way is by changing the runtime configuration of the device without updating the profile on disk.
To do that, we use the[reapply()][20] method. It requires at least the following parameters:
* the NMDevice on which to apply the new configuration;
* the NMConnection containing the configuration.
Since we only want to change the IP address and leave everything else unchanged, we first need to retrieve the current configuration of the device (also called the “*applied connection”*). Then we update it with the static address and reapply it to the device.
The applied connection, not surprisingly, can be queried with method[get_applied_connection()][21] of the NMDevice. Note that the method also returns a version id that can be useful during the reapply to avoid race conditions with other clients. For simplicity we are not going to use it.
In this example we suppose that we already know the name of the device we want to update:
```
import gi
import socket
gi.require_version("NM", "1.0")
from gi.repository import GLib, NM
# other functions here...
main_loop = GLib.MainLoop()
client = NM.Client.new(None)
device = client.get_device_by_iface("enp1s0")
device.get_applied_connection_async(0, None, get_applied_cb, None)
main_loop.run()
```
The callback function retrieves the applied connection from the result, changes the IPv4 configuration and reapplies it:
```
def get_applied_cb(device, result, data):
(connection, v) = device.get_applied_connection_finish(result)
s_ip4 = connection.get_setting_ip4_config()
s_ip4.add_address(NM.IPAddress.new(socket.AF_INET,
"172.25.12.1",
24))
device.reapply_async(connection, 0, 0, None, reapply_cb, None)
```
Omitting exception handling for brevity, the reapply callback is as simple as:
```
def reapply_cb(device, result, data):
device.reapply_finish(result)
main_loop.quit()
```
When the program quits, we will see the new address configured on the interface.
### Conclusion
This article introduced the D-Bus and libnm API of NetworkManager and presented some practical examples of its usage. Hopefully it will be useful when you need to develop your next project that involves networking!
Besides the examples presented here, the NetworkManager git tree includes [many others][22] for different programming languages. To stay up-to-date with the news from NetworkManager world, follow the [blog][23].
### References
* [NetworkManager documentation][24]
* [PyGObject documentation][25]
* [Notes on GMainLoop and GMainContext][26]
* [Notes on NetworkManager D-Bus API][27]
--------------------------------------------------------------------------------
via: https://fedoramagazine.org/using-python-and-networkmanager-to-control-the-network/
作者:[Beniamino Galvani][a]
选题:[lkxed][b]
译者:[译者ID](https://github.com/译者ID)
校对:[校对者ID](https://github.com/校对者ID)
本文由 [LCTT](https://github.com/LCTT/TranslateProject) 原创编译,[Linux中国](https://linux.cn/) 荣誉推出
[a]: https://fedoramagazine.org/author/bengal/
[b]: https://github.com/lkxed
[1]: https://fedoramagazine.org/wp-content/uploads/2022/08/python_and_networkmanager-816x345.jpg
[2]: https://unsplash.com/es/@tvick?utm_source=unsplash&utm_medium=referral&utm_content=creditCopyText
[3]: https://unsplash.com/s/photos/computer-network?utm_source=unsplash&utm_medium=referral&utm_content=creditCopyText
[4]: https://networkmanager.dev/
[5]: https://www.freedesktop.org/wiki/Software/dbus/
[6]: https://fedoramagazine.org/wp-content/uploads/2022/08/d-feet-objects.png
[7]: https://fedoramagazine.org/wp-content/uploads/2022/08/dev.png
[8]: https://networkmanager.dev/docs/api/latest/
[9]: https://fedoramagazine.org/wp-content/uploads/2022/08/libnm.png
[10]: https://networkmanager.dev/docs/libnm/latest/NMDeviceWifi.html
[11]: https://networkmanager.dev/docs/libnm/latest/NMDeviceVlan.html
[12]: https://gi.readthedocs.io/en/latest/
[13]: https://gi.readthedocs.io/en/latest/users.html
[14]: https://pygobject.readthedocs.io/en/latest/
[15]: https://networkmanager.dev/docs/libnm/latest/NMDevice.html
[16]: https://networkmanager.dev/docs/libnm/latest/NMClient.html#nm-client-add-and-activate-connection-async
[17]: https://networkmanager.dev/docs/libnm/latest/ch03.html
[18]: https://en.wikipedia.org/wiki/Event_loop
[19]: https://developer.gnome.org/documentation/tutorials/main-contexts.html
[20]: https://networkmanager.dev/docs/libnm/latest/NMDevice.html#nm-device-reapply-async
[21]: https://networkmanager.dev/docs/libnm/latest/NMDevice.html#nm-device-get-applied-connection-async
[22]: https://gitlab.freedesktop.org/NetworkManager/NetworkManager/-/tree/1.40.0/examples
[23]: https://networkmanager.dev/blog/
[24]: https://networkmanager.dev/docs/developers/
[25]: https://pygobject.readthedocs.io/en/latest/
[26]: https://developer.gnome.org/documentation/tutorials/main-contexts.html
[27]: https://networkmanager.dev/blog/notes-on-dbus/