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OOP theory vs practice
(lemmy.ml)
Post funny things about programming here! (Or just rant about your favourite programming language.)
Been working in Clojure for over a decade now, and would never never go back to using imperative/OOP at this point.
TBH Rust is pretty nice, it borrows (pun intended) a lot of ideas from the functional world (algebraic data types, traits, closures, affine types to an extent, composition over inheritance, and the general vibe of type-driven development), but it's much easier to write fast, efficient code, integrate with decades of libraries in imperative languages, and the ecosystem somehow feels mature already.
Rust solves a specific problem, and it's good at letting you write correct programs with low resource usage. It's definitely a huge improvement on C and C++.
That said, I find a language like Clojure is far more productive because it's more expressive, and development is done interactively. With Clojure, you start up your program, connect the editor to it, and evaluate code as you go seeing changes live. Once you've worked this way, it's really hard to go back to having to compile your whole program each time you want to see what it's doing. It's like having a conversation with the compiler. It makes it very easy to experiment with different ways to solve a problem, and it gives a lot of confidence because you always see exactly what the code is doing. Clojure also interops with JVM and Js runtimes, so those entire ecosystems are available for use.
Incidentally, there's a Lisp style language that embraces a lot of Rust principles. https://github.com/carp-lang/Carp
I agree that they fit different niches! My point was that with modern CPU architectures, imperative languages make it much easier to write fast&efficient code just because the hardware was pretty much engineered with C in mind. IMHO Rust offers the best of both worlds when it comes to systems/low-level dev.
That's not actually true, modern architecture works much closer to the way functional languages work https://queue.acm.org/detail.cfm?id=3212479
Modern C compilers are a fascinating blend of functional and imperative, that's true; and I didn't say that C is "close to how the modern architectures work". However, mainstream modern architectures are almost always engineered with C in mind primarily, and this is also acknowledged in the article you've linked. Rust, having a lot of similarities to C in terms of its underlying memory model, calling conventions, and control flow primitives, can often benefit from those hardware patterns and optimizations in a way that's more difficult to replicate with a functional language (especially so given most of them are GC-d due to their memory model). The closest I've seen in terms of easy-to-write-quick-code is OCaml, but even there the fast paths are often written in a very much imperative style. Idris2 also seems promising if they manage to get a GC-less mode working. Maybe also Roc, but I've not taken a look at it yet.
Note that I write all of this as someone spending a lot of their work time programming in a functional language (Haskell), with Rust being mostly for hobby stuff. It just always surprises me how much easier it is to write fast code in Rust, and yet also how much of my Haskell intuition was applicable when I was learning it.
Typically this is true, but it's certainly possible to get comparable performance with functional style. Carp, which I linked above, basically uses the same approach to memory management as Rust. It doesn't rely on GC.
I also find that for most cases it really doesn't matter all that much unless you're in a specific domain like writing drivers, making a game engine, etc. Computers are plenty fast nowadays, and ergonomics tend to be more important than raw performance.
It's possible, but you have to specifically write code that's fast, rather than idiomatic or ergonomic, and you have to know what you're doing. At that point, you may have been better off writing it in something else. I feel like OCaml is good at this because it allows you to write abstractions and main control flow in a functional way and hot paths in an imperative way without switching language, but so is Rust.
I'll take a look, thanks!
I mostly agree with you, e.g. Haskell and Clojure, despite being "slow", are plenty fast for what they're used for. On the other hand, I'm very much annoyed when "user-facing" software takes way too long to load or do simple tasks. Java in particular is pretty bad at this: JOSM (Java OpenStreetMap editor) takes longer to load than my entire desktop startup, including a window manager and browser. Unfortunately it's also the best editor around, so I pretty much have to use it to edit OSM, but it still annoys me to no end. Unnecessary computations, IO inefficiencies and layers of wrapping also affect the power consumption quite noticeably.
Functional programming tends to get conflated with static typing and immutability, but it's a much broader paradigm than that. I find it really depends on the specific language. It's very easy to do local mutation in Clojure for example. There are constructs like transient specifically designed for doing that. There are also languages like Janet that are functional, but use mutable constructs by default and can embed in C with very low footprint.
I generally get annoyed with software being slow to startup and hogging resources as well, but that's a separate discussion. The JVM is designed primarily for servers where you have long running processes, and startup time isn't really a big concern. So, it's not the best illustration. A CL app written using something like clog will be very snappy.
Joe Armstrong made a good point a while back as well. He pointed out that it's better to focus on making the compiler smarter so that it can do the optimize performance, and optimize languages for human readability. I very much agree with that sentiment. We can see an example of that being done with GraalVM which can compile JVM bytecode into optimized native apps that have very fast startup time and use far less resources than the JVM. At the moment it's not comprehensive, but you can make GUI apps with it, and they'll even run on RPi.