Flat origami is Turing complete (2023)

40•PaulHoule•11mo ago

Comments

gnabgib•11mo ago

Related How to Build an Origami Computer (63 points, 2024, 15 comments) https://news.ycombinator.com/item?id=39191627

NooneAtAll3•11mo ago

> we prove that flat origami, when viewed as a computational device, is Turing complete, or more specifically P-complete

...aren't those mutually exclusive?

I feel a mix of "those are obviously different complexity levels" and "is it like C pre-processor turing-completeness situation?"

lambdaone•11mo ago

My understanding of this is that P-completeness for a problem implies that any problem in P can be transformed into it with a polynomial-time reduction. Deterministic Turing machines (more precisely, the problem of determining the future state of a deterministic Turing machine) are in P.

tromp•11mo ago

Not with a polynomial-time reduction though. Quoting from [1]:

> Generically, reductions stronger than polynomial-time reductions are used, since all languages in P (except the empty language and the language of all strings) are P-complete under polynomial-time reductions.

[1] https://en.wikipedia.org/wiki/P-complete

cartoffal•11mo ago

Turing completeness and P completeness are completely different things. There is no sense in which P-completeness is a "more specific" version of Turing-completeness.

gitroom•11mo ago

Honestly wild how you can get Turing completeness outta folding paper, never thought I'd read that today.

StopDisinfo910•11mo ago

That's why I have always prefered Church approach to computation to Turing machines.

The lambda calculus, by its simplicity as just a rewriting language, makes it "obvious" how effective computability emerges from very little.

yorwba•11mo ago

The reduction in the article boils down to origami crease patterns simulating rule 110 simulating a cyclic tag system simulating a clockwise Turing machine simulating an arbitrary Turing machine (and specific Turing machines simulating the lambda calculus are known).

Do you think there is an "obvious" way to simulate the lambda calculus using origami crease patterns more directly? For example, a cyclic tag system or even rule 110 configuration simulating the lambda calculus without indirection through Turing machines.

entaloneralie•11mo ago

If I may chip in, I wouldn't call it obvious or straight-forward, but multiset rewriting[1] can be implemented in terms of multiplication alone(like in Fractran), and multiplication can be implemented in origami[2], so there might be something there.

[1] https://wiki.xxiivv.com/site/pocket_rewriting

[2] https://wiki.xxiivv.com/site/paper_product.html

PaulHoule•11mo ago

It's a big controversy in CS education, isn't it?

Knuth's Art of Computer Programming was built around assembly language for a fantasy computer which is inspired more or less by the Turing machine (program counter is an index into a program 'state', instructions transform a data 'state' and transition to a different program 'state') whereas Structure and Interpretation of Computer Programs is more inspired by Church.

The pinnacle of undergraduate CS education, I think, is compilers, which is where those approaches are ultimately unified on a practical level (you make a machine that transforms one to the other) but the introductory course for the non-professional programmer or the person who aspires to writing compilers someday is still pretty controversial.

StopDisinfo910•11mo ago

> It's a big controversy in CS education, isn't it?

Is it?

I think most people who have heard of the topic are familiar with the Church-Turing thesis and know that both definitions of effective calculability are equivalent.

My preference is mostly a matter of taste I think. I admire how little there is to the lambda calculus definition and how computability somehow emerges through construction and definition (which admittedly are not simple). It nicely shows that you need very little "machinery" to get a powerful computational system.

Turing machines by comparaison seem somewhat contrieved with their infinite tape, head and register even if I realise that in a lot of way they are closer to an actual computer.

entaloneralie•11mo ago

Related: Origami-Constructible Numbers[1] & Folding Primes[2]

[1] https://www.cs.mcgill.ca/~jking/papers/origami.pdf

[2] https://www.pythabacus.com/Origami%20Fractions/folding.htm

Project Glasswing: Securing critical software for the AI era

Lunar Flyby

Protect your shed

Sonnet 4.6 Elevated Rate of Errors

Slightly safer vibecoding by adopting old hacker habits

Native Americans had dice 12k years ago

System Card: Claude Mythos Preview [pdf]

Revision Demoparty 2026: Razor1911 [video]

GLM-5.1: Towards Long-Horizon Tasks

How to get better at guitar

Binary obfuscation used in AAA Games

S3 Files

Cambodia unveils statue to honour famous landmine-sniffing rat

Show HN: An interactive map of Tolkien's Middle-earth

A truck driver spent 20 years making a scale model of every building in NYC

Show HN: Brutalist Concrete Laptop Stand (2024)

A database of analog cameras that can be 3D printed

The Clock

US and Iran agree to provisional ceasefire

Cloudflare targets 2029 for full post-quantum security

Xilem – An experimental Rust native UI framework

Show HN: Gemma 4 Multimodal Fine-Tuner for Apple Silicon

A whole boss fight in 256 bytes

JSIR: A High-Level IR for JavaScript

Rescuing old printers with an in-browser Linux VM bridged to WebUSB over USB/IP

The Image Boards of Hayao Miyazaki

ACE on a USB-HDMI Adapter

Running out of disk space in production

Google open-sources experimental agent orchestration testbed Scion

A blind man made it possible for others with low vision to build Lego sets