I’ve heard of immutable OS’s like Fedora Silverblue. As far as I understand it, this means that “system files” are read-only, and that this is more secure.
What I struggle to understand is, what does that mean in practical terms? How does installing packages or configuring software work, if system files can’t be changed?
Another thing I don’t really understand is what the benefits as an end user? What kinds of things can I do (or can be done by malware or someone else) to my Arch system that couldn’t be done on an immutable system? I get that there’s a security benefit just in that malware can’t change system files – but that is achieved by proper permission management on traditional systems too.
And I understand the benefit of something declarative like NixOS or Guix, which are also immutable. But a lot of OS’s seem to be immutable but not purely declarative. I’m struggling to understand why that’s useful.
applications are installed with flatpak - basically little containers that contain everything a program needs. sort of like docker
so normally if you wanna install something - let’s say minecraft. you would also need to install java. the flatpak for minecraft would have java inside of it so it can be run in its own little container and you don’t need to install either
Doesn’t that lead to huge redundancy – say, multiple java copies effectively existing in the system? And also to software not optimized for the system (I assume flatpaks are pre-compiled)?
You’re right - having multiple copies of everything is a drawback of housing each application in its own container or VM. The standard rejoinder is that disk space is cheap. The validity of that rejoinder depends on what you’re doing and what hardware or budget you are working with.
Another problem is that old versions of these dependencies will be baked into an image that is then used for many years without updates. This ensures the application keeps working without being disrupted by an update to a shared library, but it also means things like security flaws persist. Arguably, this is mitigated by only that image having the problem, but one insecure app can be a real problem - especially when it accesses shared resources - and when the same problem applies to many applications.
Compiled code optimized for a specific system’s hardware is less relevant than it used to be - even Gentoo users do not focus on this anymore. Rolling your own container isn’t much harder than compiling with your own options.
Flatpaks really have the added benefit of things just work. Many distros have problems with codecs for example and need to install extra packages to get video working in Firefox. The flatpak version doesn’t require any of this and you can just install and move on with your life. Yes dependencies are “redundant” sometimes but you have the added benefit of a really clean base system without hundreds or thousands of lib or dev packages. Also sometimes you need a specific version of a dependency. Let’s say you need to update it for compatibility with a specific package but that breaks another which needs an older version. The system can stay especially clean when it comes to the toolbox utility and dev environments (this is available in other distros as distrobox I think).
I guess what I am trying to figure out is – how would the experience of using flatpak or other containerized software managers differ on an immutable system compared to a mutable one?
Or is the idea more that since you’re containerizing, you can lock everything else for stability in a way that you couldn’t before, because software installs needed to be installed in the system?
It’s this one. For example, with Silverblue, applications are all installed as flatpaks. The system level files are also made as read-only as possible, such that the base systems should look virtually identical across systems. You also get some like NixOS where most of the system setup is defined in a single config file. You can effectively copy your entire setup just by transplanting that file on a new system.