There’s languages designed with Capabilities in mind. Like, whatever starts the program gets to decide what functionality is exposed to the running program. It’s great for situations where you might run untrusted code and want to, as an example, not allow network access, or filesystem access.
More generally there’s also sandboxing techniques that runtimes provide. Webassembly for instance is designed for programs to run in their own memory space with a restricted set of functions and, again, Capabilities. This might be nice if you ever work on a cloud application that allows users to upload their own programs and you want to impose limits on those programs. Think AWS Lambda, except the programs running wouldn’t necessarily even have access to the filesystem or be able to make web requests unless the user configures that.
It might be a good design space for even more esoteric areas, like device drivers. Like, why worry if your GPU drivers are also collecting telemetry on your computer if you can just turn off that capability?
There’s older applications of sandboxing that are a bit further from what you’re asking as well; like, iframes on a webpage; allowing code served from different servers you don’t necessarily control to run without needing to worry about them reading access tokens from local storage.
Or even BSD Jails and chroot.
Good question 💖
I guess a more modern example you might run into is something like Rust’s no_std environment; which strips out the standard library of the language that doesn’t work on every device the language is designed to target (namely microcontrollers that don’t even have an operating system on them). Or like, maybe you’re writing your own operating system.
Another example comes to mind of a company, General Magic, that designed a programming language with a similar Capabilities system meant to restrict access to functions and code on their devices with the idea of copyright enforcement in mind as a primary use case. There’s a documentary about the device if you’re interested: https://www.generalmagicthemovie.com
I think Roc has some ideas like this.
On a sandboxing level, I suppose we’d be talking about Unikernels (which seem cool, but the tooling didn’t look simple enough to experiment with them)
Deno is an example of a language runtime (based on Javascript+Typescript) that’s been built with capabilities in mind. By default, programs aren’t allowed to touch the filesystem or network (except to allow static imports to run; fallible dynamic import calls that could be used to determine something about the filesystem or network are restricted like other IO). Programs can start up worker threads that have further permission restrictions than the main program.
Not a language per se, but subsets of languages used for fantasy consoles usually do not implement import functionality. TIC-80, PICO-8, etc. etc. WIKI I wouldn’t call that a feature, but it drives you to write less and more space-optimized code.
Now that I think about it, source code size could be a feature in itself, look at codeGolf-oriented esolangs:- Pyth
- CJam
- GolfScript
- Microscript/Microscript II
- Seriously
- Rotor
- Minkolang
- Gaia
- Jelly
- 05AB1E
- japt
- and more…
You could check brainfuck, which is designed for extreme minimalism, though not for usefulness (quite the opposite in fact).
I’m not smart enough to know, but what kind of use case(s) do you imagine for this?
I know encapsulation is desirable in part because of security. I figured something similar could happen by removing the ability to import anything from another program. However, I struggled to think about other situations in which no imports were desirable, and so I wondered…
There are certainly situations where it would be valuable to be able to place limits on what can be imported, but I can’t imagine trying to work with a language that was completely devoid of imports. Because that would mean 100% of your source would have to be in a single file, which sounds absolutely awful for anything but the most trivial applications.