Lambda Calculus in 383 Bytes (2022)
(justine.lol)310 points by MrBuddyCasino 6 days ago
310 points by MrBuddyCasino 6 days ago
The best way to wrap your mind around the core concept and internalize them into a mental model is writing an interpreter yourself. It's been abundantly clear to me since young that for anything involving math, you don't internalize it if you merely passively let someone else explain it, whether that's reading a textbook/blog or attending a professor's lecture or watching a YouTube video. You have to do the exercises.
Lambda calculus is the same. You can easily define the data structure to represent a program in untyped lambda calculus and then write an interpreter for it. Then go implement some interesting concepts such as the Y combinator or the Omega combinator. If you find lambda calculus too difficult to do things like arithmetic or linked lists, you don't have to stick with Church numerals or Scott encodings. Just introduce regular natural numbers and lists as ground types; when you later have a better understanding, write programs to transform regular numerals from and to Church numerals and bask in the fact that they are isomorphic.
Mathematics is not a spectator sport.
I had the luck of reading that quote while I was an undergrad. I did not actually pursue a career in pure math, but it certainly helps me every time I want to understand some math in order to apply it. (Lambda calculus, type systems, Fourier/Laplace/z-transform, ...)
I agree that you have to do the exercises instead of expecting others to explain and walk you through it.
https://www.youtube.com/watch?v=LXhsutNKhec
Just one programming book was able to help my son, who is 12 yrs old, learn lambda calculus and write a meta circular evaluator.
I think the most ELI5 approach is Alligator Eggs [0] which was built for 8-year-olds to play like a game. You can find a lot of the advanced concepts outside of the core also explained in terms of Alligator Eggs and some software visualizers, but there's also something to be said about hands on learning and about printing it out yourself on some cardstock or cardboard paper, cutting it out, personalizing it with crayons, and playing it with a child or at least your inner child.
It's too basic for what you need but the video from eyesomorphic [1], is a wonderful conceptual introduction
> Whilst it certainly isn't a contender for modern programming languages
Yet all that separates the λ-calculus from one modern programming language, Haskell, is a layer of syntactic sugar on top, and a runtime that effectuates its pure IO actions. We can in fact compile Haskell programs using just stdin/stdout for IO into terms of the untyped lambda calculus, as wonderfully demonstrated in Ben Lynn's IOCCC entry [1], or equivalently, into BLC programs.
> Yet all that separates the λ-calculus from one modern programming language, Haskell, is a layer of syntactic sugar on top, and a runtime that effectuates its pure IO actions. We can in fact compile Haskell programs using just stdin/stdout for IO into terms of the untyped lambda calculus, as wonderfully demonstrated in Ben Lynn's IOCCC entry [1].
That's what Turing completeness means, though; you can do the same thing with C, with the same provisos. (Conal Elliott has an amusing satire on this: http://conal.net/blog/posts/the-c-language-is-purely-functio... .) It's not that the lambda calculus isn't sufficiently expressive, just that it's not a language in which humans want to write.
For anyone who's interested - Ben Lynn also has a series of articles that explain the creation of that compiler and add further enhancements:
video author is using 3b1b's manim (https://github.com/3b1b/manim). wonderful presentation.
"To mock a mockingbird" (https://en.wikipedia.org/wiki/To_Mock_a_Mockingbird) is a wonderful introduction to something that's sufficiently more abstract than lambda calculus that you'll probably find the latter pleasingly concrete afterwards, but it takes only tiny, bite-sized steps (err, mixed metaphors) to get you to understanding.
You might find my practical introduction to lambda calculus and combinatory logic based on javascript helpful. [1]
Its mostly based on other introductory resources but I tried to write it from a practical step by step perspective I found most useful for myself.
If you have some time to spare, read SICP [0] and do the exercises :) (probably easiest to use DrRacket [1] as the interpreter)
[0] https://mitp-content-server.mit.edu/books/content/sectbyfn/b...
[1] https://docs.racket-lang.org/sicp-manual/SICP_Language.html
Spending time with pure functional programming (languages like Haskell) will open up these concepts in a real-world programming environment. Obviously languages like Haskell are more complex than this, but they're all fundamentally based on lambda calculus. That could be the first step away from the imperative thinking you describe.
(That was certainly my way in to this world anyway!)
sorry for not providing explanations, but check this out: https://tromp.github.io/cl/diagrams.html
did you see https://news.ycombinator.com/item?id=42256394 (The Art and Mathematics of Genji-Ko 172 points, by olooney, 49 days ago, 10 comments)? very tangentially related, but also mesmerizing stuff, i think..
Author here. If anyone wants to see an example of an awesome program you can run on the 520 byte version of my lambda calculus virtual machine (Blc) then check out https://github.com/woodrush/lambdalisp If you run the command in that project, it'll download my VM from the blog post, build a 20kb lambda expression you can pipe into it, and BOOM a fully object-oriented LISP REPL will appear in your terminal. It's like magic. For an example expression, try typing (+ 2 3) and hit enter. Then type (let ((a 2) (b 3)) (+ a b)) and hit enter. You need an x86 linux machine to do this right now.
Justine - thanks so much for all these amazing projects. You're an inspiration.
One thing I saw you write recently is that chasing the newest fads is a distraction. That makes sense, but if you don't mind me asking, what do you think one should focus on instead? Which are the classic languages, tools, mindsets, and CS concepts that one must master?
Hi troad, I read your book: https://justine.lol/sectorlisp2/troades.html
I don't remember saying that. You might be thinking about https://justine.lol/ape.html where I said we should be focusing on the old things that matter which aren't going away, like UNIX magic numbers, C libraries, and computer science. But I've got nothing against the new. I think AI for example is exciting. Ultimately you should focus on whatever summons your passion and curiosity. Since if you're tapped into that divine energy within, then you can make anything work, and others will agree. Even if it's just boring old numbers.
I don't know if it will work for you, but I wrote a Quicksort using lambda calculus in Python, and I explained the process of writing it here:
https://lucasoshiro.github.io/software-en/2020-06-06-lambdas...
Please note that I'm not an expert in lambda calculus, just a curious nerd and it won't explain everything, like the reductions, combinators and so on. But there I explain how to implement simple types (int, boolean, pairs and lists) using Church encoding, let expressions and recursion using the Y combinator (yay, I finally used the expression "Y combinator" on HN!). Everything that we need to implement a quicksort (which is a relatively complex algorithm) using the almost nothing that we have in lambda calculus.
Another point is that it's all implemented in Python, using the Python notation instead of the lambda calculus notation, so you can run the code in your machine and play with the examples
If the IOCCC description [1] doesn't make it clear enough, perhaps this explanation [2] does it better? I also link to a Pi Day 2023 talk trying to explain it on my lambda playground page [3].
[1] https://www.ioccc.org/2012/tromp/
[2] https://gist.github.com/tromp/86b3184f852f65bfb814e3ab0987d8...
In case the other answers aren't sufficient, the first step is to understand the λ-calculus[0]. Then, De Bruijn indices[1]. Now, observe that the language we have only has (you need familiarity with the λ-calculus to understand those terms (… pun unintended)) 1/ applications, 2/ abstractions, 3/ integers representing variables [introduced by abstractions]. For example:
(λ (λ 1 (λ 1)) (λ 2 1))
00 means abstraction (pops in the Krivine machine)
01 means application (push argument continuations)
1...0 means variable (with varint de Bruijn index)
s/9/11111111110/g
s/8/1111111110/g
s/7/111111110/g
s/6/11111110/g
s/5/1111110/g
s/4/111110/g
s/3/11110/g
s/2/1110/g
[0]: https://www.irif.fr/~mellies/mpri/mpri-ens/biblio/Selinger-L...
I think I must agree: while I went through [0] to build a λ-calculus interpreter, I already had a fair amount of practice with Church encoding (list, bool, int) using an arbitrary functional language, which retrospectively must have helped greatly to make Selinger's notes clearer.
I found this helpful https://brilliant.org/wiki/lambda-calculus/
The 43-byte implementation might define only a subset of the functionality provided by the full VM, enough to "bootstrap" into the full implementation, most likely.
In fact, if the VM is Turing complete, it can theoretically emulate any computation, including its full implementation, even from a small subset of operations.
The point is that the 43-byte implementation does not need to encode the entire VM explicitly. For example, if the VM has built-in primitives for looping, branching, and memory management, the minimal implementation can leverage these to rebuild the remaining functionality.
My IOCCC entry [1] explains exactly what the 43-byte program is. It's a self-interpreter for BLC8, the byte based version of Binary Lambda Calculus.
The 521 byte interpreter on the other hand is written in x86 assembly, a language much less suitable for writing BLC8 interpreters than BLC8 itself.
Btw, with my latest lambda compiler, the BLC8 self interpreter is only 42 bytes:
λ 1 ((λ 1 1) (λ (λ λ λ 1 (λ λ λ 2 (λ λ λ (λ 7 (10 (λ 5 (2 (λ λ 3 (λ 1 2 3)))
(11 (λ 3 (λ 3 1 (2 1))))) 3) (4 (1 (λ 1 5) 3) (10 (λ 2 (λ 2 (1 6))) 6))) 8)
(λ 1 (λ 8 7 (λ 1 6 2)))) (λ 1 (4 3))) (1 1)) (λ λ 2 ((λ 1 1) (λ 1 1))))
thanks, this is helping me understand the whole article a bit better.
Yeah, I just took a real look now. It uses a metacircular evaluator? I didn't look at the link provided just yet though! :D
"For example, its metacircular evaluator is 232 bits. If we use the 8-bit version of the interpreter (the capital Blc one) which uses a true binary wire format, then we can get a sense of just how small the programs targeting this virtual machine can be."
From TFA. I think it's a very good article.
Discussed at the time (but before it shrank):
Lambda Calculus in 400 Bytes - https://news.ycombinator.com/item?id=30493713 - Feb 2022 (63 comments)
I feel like I've accidentally stumbled into /r/VXJunkies with some of the terminology being thrown around in here.
Very interesting. Is it possible to imagine implementing an OS based on this ? I have been interested by lambda calculus for a while (implemented a lambda calculus interpreter in haskell) and was always wondering if people were working on "functional computers" and if it makes sense
Cheers,
It doesn't work on modern Apple Silicon macs with M1-4 chips (although Rosetta [1] might be able to handle it somehow), but it works fine on my older x86 based iMac.
I've been attracted to this - along with 2D cellular automata - a bit like a moth to a flame for some time. I find the little machine visualisations mesmerising, the heavily parenthesized Greek representation charming (they look like standing orders written in an alien language, looking for all the world like space invaders) and the tiny code sizes magical.
But I can't quite wrap my mind around the core concepts and internalize them into a mental model. It's too different from the simple world of imperative C or scripting languages I guess I call home. So I'm left watching das blinkenlights from the outside, as my attention span chokes on the layers of computer science incorporated into typical explanations. *shrug*
I'd be very interested if anyone knows of an ELI5-style alternate path I could walk to break each of the concepts down one at a time. (I ask because I think this is (currently) the kind of thing I think ChatGPT would struggle to present as effectively as a human.)