trompan hour ago
The author presents most known numeral systems (ways of representing natural numbers) in lambda calculus, classified by whether the term use their bound variables exactly one time (linear), at most one time (affine), or multiple times (non-linear). Mackie's paper [0] (one of the references) provides a good introduction to these.
He illustrates some numerals in each system with a graphical notation that strongly reminds me of interaction nets [1], a computational model closely related to lambda calculus. The notation they use for lambda terms is rather non-standard. Compare
> In β-reduction, k[(x⇒b)←a]⊳k[b{a/x}]k[(x⇒b)←a]⊳k[b{a/x}]
with Wikipedia's [2]
> The β-reduction rule states that a β-redex, an application of the form (λx. t) s, reduces to the term t[x:=s].
The k[...] part means that β-reduction steps can happen in arbitrary contexts.
[0] https://www.researchgate.net/publication/323000057_Linear_Nu...
lefra2 hours ago
I think I lack context to see what this is about. The line graphs are pretty though, and I'd like to understand more.
Sharlin43 minutes ago
The author unfortunately only describes about half of the syntax they use, or rather, they describe the syntax of the language but assume the reader is familiar with the (rather obscure even in a PLT context) metalanguage.
p1esk3 hours ago
I didn’t understand that notation. Can someone please explain?
ngruhn2 hours ago
I think:
x => a
λx. a
f <- a
f alefra2 hours ago
What about big T, square/angle brackets, and braces?
ngruhn2 hours ago
yeah no idea
jdw6444 minutes ago
const f = (x) => x + 1;
throwaway81523an hour ago
Hmm nice I guess, but I expected it was going to be about transfinite ordinals. I wonder if it can be extended to them.
bananaflag2 hours ago
This should be "numerals"
dnnddidiejan hour ago
This is beautiful art