C/C++ applications

Snapcraft can be used to package and distribute C and C++ applications in a way that enables convenient installation by users.

The process of creating a snap for a C or C++ application builds on standard tools like autotools and make, making it possible to adapt or integrate an application’s existing packaging into the snap building process.

Getting started

Snaps are defined in a single snapcraft.yaml file placed in a snap folder at the root of your project. This YAML file describes the application, its dependencies and how it should be built.

The following example shows the entire snapcraft.yaml file for an existing project, Moon-buggy:

snapcraft.yaml for Moon-buggy
name: moon-buggy
base: core22
version: '1.0.51'
summary: Drive a car across the moon
description: |
  Moon-buggy is a simple character graphics game, where you drive some
  kind of car across the moon's surface. Unfortunately there are 
  dangerous craters there. Fortunately your car can jump over them!

confinement: devmode

parts:
  moon-buggy:
    plugin: autotools
    autotools-configure-parameters: ["--prefix=/usr"]
    source: https://github.com/sergiusens/moon-buggy.git
    build-packages:
      - libncurses-dev
      - texinfo
apps:
  moon-buggy:
    command: usr/bin/moon-buggy

In this example we’re referencing a lightly patched version of moon-buggy, forked from the original [moon-buggy source](source: https://github.com/seehuhn/moon-buggy).

This extensive description is broken down in the following sections.

Metadata

The snapcraft.yaml file starts with a small amount of human-readable metadata, which usually can be lifted from the GitHub description or project README.md file. This data is used in the presentation of your app in the Snap Store.

name: moon-buggy
version: '1.0.51'
summary: Drive a car across the moon
description: |
  Moon-buggy is a simple character graphics game, where you drive some
  kind of car across the moon's surface. Unfortunately there are 
  dangerous craters there. Fortunately your car can jump over them!

The name must be unique in the Snap Store. Valid snap names consist of lower-case alphanumeric characters and hyphens. They cannot be all numbers and they also cannot start or end with a hyphen.

By specifying git for the version, the current git tag or commit will be used as the version string. Versions carry no semantic meaning in snaps.

The summary can not exceed 79 characters. You can use the pipe symbol ‘|’ in the description key to declare a multi-line description.

Base

The base keyword declares which base snap to use with the project. A base snap is a special kind of snap that provides a run-time environment alongside a minimal set of libraries that are common to most applications.

base: core22

In this example, core22 is used as the base for snap building, and is based on Ubuntu 22.04 LTS. See Base snaps for more details.

Security model

Snaps are containerised to ensure more predictable application behaviour and greater security. Unlike other container systems, the shape of this confinement can be changed through a set of interfaces. These are declarations that tell the system to give permission for specific tasks, such as accessing a webcam or binding to a network port.

The next section describes the level of confinement applied to the running application:

confinement: devmode

It is best to start creating a snap with a confinement level that provides warnings for confinement issues instead of strictly applying confinement. This is done by specifying the devmode (developer mode) confinement value.

When a snap is in devmode, runtime confinement violations will be allowed but reported. These can be reviewed by running journalctl -xe.

Because devmode is only intended for development, snaps must be set to strict confinement before they can be published as “stable” in the Snap Store. Once an application is working well in devmode, you can review confinement violations, add appropriate interfaces, and switch to strict confinement.

The above example will also work if you change the confinement from devmode to strict, as you would before a release.

Parts

Parts define what sources are needed to build your application. Parts can be anything: programs, libraries, or other needed assets, but for this example, we only need to use one part: the Moon-buggy git repository.

The plugin keyword is used to select a language or technology-specific plugin that knows how to perform the build steps for the project. In this example, the autotools plugin is used to automate the build, using the standard configure and make tools to build the part.

We use the autotools-configure-parameters option of the autotools plugin to override the --prefix, which would default typically default to /usr/local. While not strictly necessary, it’s useful here to illustrate the use of autotools-configure-parameters.

parts:
  moon-buggy:
    plugin: autotools
    autotools-configure-parameters: ["--prefix=/usr"]
    source: https://github.com/sergiusens/moon-buggy.git
    build-packages:
      - libncurses-dev
      - texinfo

Before building the part, the packages listed in the build-packages section need to be installed in the build environment. These are the tools and libraries that are used during the build process.

For this snap, there is no stage-packages section specified, because all the moon-buggy binary doesn’t require any.

It is common for larger, more complex applications to depend on other libraries. The stage-packages section would be used to list the packages containing those run-time dependencies.

For more details on autotools-specific metadata, see The autotools plugin.

Apps

Apps are the commands you want to expose to users, and also the names of any background services the application provides. Each key under apps is the command name that should be made available on users’ systems.

The command specifies the path to the binary to be run. This is resolved relative to the root of the snap contents. In our example, we have overridden the installation path from usr/local/bin to usr/bin in the parts section, above.

apps:
  moon-buggy:
    command: usr/bin/moon-buggy

If the command name matches the name of the snap specified in the top-level name keyword (see the Metadata section above), the binary file will be given the same name as the snap, as in this example. If the names differ, the binary file name will be prefixed with the snap name to avoid naming conflicts between installed snaps. An example of this would be moon-buggy.some-command.

If your application is intended to run as a service you simply add the line daemon: simple after the command keyword. This will automatically keep the service running on install, update, and reboot.

Building the snap

You can download the example repository with the following command:

git clone https://github.com/snapcraft-docs/moon-buggy

After you’ve created the snapcraft.yaml file (which already exists in the above repository), you can build the snap by simply executing the snapcraft command in the project directory:

$ snapcraft
Using 'snapcraft.yaml': Project assets will be searched for from the 'snap' directory.
Launching a VM.
[...]
Snapped moon-buggy_1.0.51_amd64.snap

The resulting snap can be installed locally. This requires the --dangerous flag because the snap is not signed by the Snap Store. The --devmode flag acknowledges that you are installing an unconfined application:

sudo snap install moon-buggy_*.snap --devmode --dangerous

You can then try it out:

moon-buggy

(screenshots)

Removing the snap is simple too:

sudo snap remove moon-buggy

You can clean up the build environment with the following command:

snapcraft clean

By default, when you make a change to snapcraft.yaml, snapcraft only builds the parts that have changed. Cleaning a build, however, forces your snap to be rebuilt in a clean environment and will take longer.

Publishing your snap

To share your snaps you need to publish them in the Snap Store. First, create an account on the dashboard. Here you can customise how your snaps are presented, review your uploads and control publishing.

You’ll need to choose a unique “developer namespace” as part of the account creation process. This name will be visible by users and associated with your published snaps.

Make sure the snapcraft command is authenticated using the email address attached to your Snap Store account:

snapcraft login

Reserve a name for your snap

You can publish your own version of a snap, provided you do so under a name you have rights to. You can register a name on dashboard.snapcraft.io, or by running the following command:

snapcraft register mysnap

Be sure to update the name: in your snapcraft.yaml to match this registered name, then run snapcraft again.

Upload your snap

Use snapcraft to push the snap to the Snap Store.

snapcraft upload --release=edge mysnap_*.snap

If you’re happy with the result, you can commit the snapcraft.yaml to your GitHub repo. You can optionally enable Build from GitHub so any further commits automatically get released to edge, without requiring you to manually build locally.

Congratulations! You’ve just built and published your first C/C++ snap. For a more in-depth overview of the snap building process, see Creating a snap.

Copied verbatim from the old docs at https://github.com/canonical-docs/snappy-docs/edit/master/build-snaps/c.md

For this to build properly, a couple changes should be made in the GitHub repo. First, it appears that “freeglut3” needs to be added to stage-packages, to resolve need for libglut.so.3.

Also, not critical, but apps section should have “command: bin/dosbox” to avoid getting a warning when packaging.

I will take care of fixing typos on this page.

P.S. For consistency, the GitHub repo might want to move snapcraft.yaml under the snap/ directory.

1 Like

Oh, and to avoid another warning, add “grade: stable” to snapcraft.yaml.

The first paragraph of this tutorial mentions “Python applications”, this is probably a copy’n’paste error, and should instead say “C/C++ applications”?

Snapcraft can be used to package and distribute Python applications in a way that enables convenient installation by users.

Also, the snapcraft.yaml in this tutorial uses an old base (core18) and has things like "DISABLE_WAYLAND": "1" , which might make a casual observer wonder if Snap doesn’t support Wayland (it does!)?

For a more up-to-date example of a DOSBox-like Snap that’s using core22 as the base, even though it still sets "DISABLE_WAYLAND": "1" in the environment, DOSBox-X (a well-maintained fork of DOSBox) is available from Snapcrafters:

https://github.com/snapcrafters/dosbox-x/blob/master/snap/snapcraft.yaml

Thanks for the suggestion, and for the suggested snap. You’re absolutely right about this example needing to be updated. I’ve created a task to do this.

Hello everyone!

Just a quick note, the link for:

turn on automatic builds

Seems to be broken, I believe it should be this one::

Many thanks!

Hello! Thanks for letting us know about the link. I think the new destination should likely be Build from GitHub, which I’ve just edited in.

Also, huge thanks to @popey who took the trouble to update this guide as part of the Open Documentation Academy.

2 Likes

Perhaps a sentence about CMake could be interresting if Autotools fails. Note: I just discover Cmake today.