Theory of Computing Report

Authors: Melissa Antonelli, Arnaud Durand, Rui Li

Authors: Jack Stade

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Authors: Meysam Alishahi, Alexander Munteanu, Simon Omlor, Jeff M. Phillips

Authors: Akash Kumar, Abhiruk Lahiri, C. Seshadhri

Authors: Nicholas Zhao

Authors: Sander Borst, Max Springer

Authors: Niels Holtgrefe, Jannik Schestag

Authors: Diptarka Chakraborty, Arya Mazumdar, Barna Saha, Alvin Hong Yao Yan

Authors: Mugen Blue, Sungjin Im, Alexander Lindermayr

Authors: Clément L. Canonne, Yash Pote, Jonathan Scarlett, Joy Qiping Yang

In a 1946 paper in the American Mathematical Monthly, Paul Erdős posed the Erdős Distinct Distance Problem and the Erdős Unit Distance Problem.

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THE ERDŐS DISTINCT DISTANCE PROBLEM

A nice high school math competition problem, if it were not fairly well known, is:

Show that for all sets of \(n\) points in the plane, there are at least \(0.5\sqrt{n}\) distinct distances.

A bit harder is to show that there exist \(n\) points in the plane where the number of distinct distances is \(O(\frac{n}{(\log n)^{1/2}})\). The points are the grid points of a \(\sqrt{n}\times\sqrt{n}\) integer grid. 

ADDED LATER:  The set of points is \(\{ (x,y) \in Z\times Z   \colon    1\le x,y\le \sqrt{n}   \} \)

Let \(g(n)\) be the minimum number such that, for every set of \(n\) points in the plane,
there are \(g(n)\) distinct distances. The above results (of Erdős) show that

\( \Omega(n^{1/2}) \le g(n) \le O(\frac{n}{(\log n)^{1/2}}) \)

Erdős made no conjecture about \(g(n)\) in that 1946 paper. However, later papers attribute to him one of two conjectures:

1) \( (\forall \epsilon)[g(n)\ge n^{1-\epsilon}]\)

or

2) \(g(n) = \Omega(\frac{n}{(\log n)^{1/2}})\)

Those papers incorrectly point to the 1946 paper for where he made those conjectures.  I suspect he made those conjectures later in talks or compilations of open problems.

This was a great problem in that there were many papers making progress on it, each one having new ideas. The current best result is that \(g(n) \ge \Omega(\frac{n}{\log n})\).  This result was obtained by Larry Guth and Netz Katz in 2011 and is, by far, the largest leap forward in progress on the problem.  Brass-Moser-Pach (2005) and later Pach-Sharir (2009) observed that existing techniques could never prove \(g(n) \ge \Omega(n^{8/9+\epsilon})\).  I've also heard the observation credited to Rusza. Guth and Katz invented (discovered?) new techniques to obtain their breakthrough.

See my webpage of all papers on the problem here or the Wikipedia page here

Takeaway: The Erdős Distinct Distance Problem saw decades of steady human progress and was eventually almost completely resolved without computer assistance.  I would not have emphasized without computer assistance one year ago.  Maybe not even one week ago.

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THE ERDŐS UNIT DISTANCE PROBLEM

Let S be a set of \(n\) points in the plane. Some of the distances between points of S may be 1. How many?  What is the maximum number of unit distances that can occur? Denote this by \(f(n)\). Erdős showed

\( n^{1+\Omega(1/\log\log n)} \le f(n) \le O(n^{3/2}) \).

The lower bound is obtained by using the grid points of a scaled version of the \(\sqrt{n}\times\sqrt{n}\) integer grid. See a writeup by ChatGPT,   here.  We note for later that this can be phrased as using the points in the Gaussian integers, \(Z[i]\).  

In the 1946 paper Erdős conjectured that, for all \(\epsilon\),  \(f(n) = O(n^{1+\epsilon})\).

Joel Spencer, Endre Szemerédi, and William Trotter in 1984 showed \(f(n) = O(n^{4/3})\).

Aside from the Spencer-Szemerédi-Trotter bound, there has been relatively little progress on either the upper or lower bound.

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CONTRASTING THE TWO PROBLEMS

Contrast: The Erdős Distinct Distance problem has seen extensive progress and a large literature. By contrast, although many papers were written on the Erdős unit distance problem, there was little improvement. That changed on May 20, 2026.

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OPENAI PRODUCES A COUNTEREXAMPLE TO THE ERDŐS CONJECTURE

OpenAI recently produced a counterexample to Erdős's conjecture.  More precisely, OpenAI proved the following:

There exists \(\epsilon>0 \) and a sequence of point  sets \(P_i \subseteq R^2\) such that, letting \(|P_i|=n_i\):

a) \(n_i \rightarrow\infty\), and

b) for all \(i\), the number of unit distances in \(P_i\) is at least \(n_i^{1+\epsilon}\).

The  OpenAI announcement is here. The technical paper is here. 

Note that the author is OpenAI. There are no human co-authors.  However,(1)  Lije Chen used an internal OpenAI model and (2) Mark Selke and Metaab Sawhney verified correctness. The \(\epsilon\) is not given though one could go through the paper and find it. It would be very small. 

After the initial AI-generated argument (or AI-assisted?) human mathematicians streamlined and clarified the proof. The result is a paper by Noga Alon, Thomas Bloom, W.T. Gowers, Daniel Litt, Will Sawin, Arul Shankar, Jacob Tsimermann, Victor Wang, and Melanie Matchett Wood  that explains the history, the proof, and their reactions to it. That paper is here. They obtain \(\epsilon \sim 6\times 10^{-38}\). 

Recall that Erdős's lower bound was obtained by using points in \(Z[i]\). The new result used more complicated number fields. Indeed, the degree of the number fields used goes to infinity.  For more details see the Alon et al. proof.  

Will Sawin wrote a paper where he obtained \(\epsilon=0.014114\). Quoting his paper:

To do this, we make explicit and sharpen every step of the argument. Interestingly, this rarely makes the argument much more complex. The total length of this paper is essentially the same as the original OpenAI writeup, though longer than the simplified version prepared by human authors [Alon et a.].

His paper is here

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 MY POINTS

1) The Erdős's Unit Distance problem is a well known and interesting conjecture, so this is not picking out some obscure problem.

2) AI-generated or AI-assisted? The announcement by OpenAI, and the Alon et al. paper, indicate that the proof is AI-generated.

Fellow blogger Gary Marcus disagrees and argues that it is AI-assisted.  See his post here. 

ADDED LATER: An interview with Gary Marcus is 

I think this is a hard question, and perhaps there is more of a continuum.  However, I trust Alon et al., so I will go with AI-generated.

3) Humans were still needed to verify and  clean up the proof. In the future, we will all be grad students, verifying and cleaning up what AI outputs.

4) The final proof was readable. One concern about AI proofs is that they would be unreadable and hard to verify. That was not the case here.

5) The ideas needed for the solution already existed; however:

a) The right combination was hard to find.

b) The relevant techniques used, algebraic number theory, are not standard tools in combinatorial geometry.

c) It was widely believed that Erdős's conjecture was true.

d) Producing a counterexample seems less impressive than proving the theorem.  It would be of interest to see if OpenAI could prove the Guth-Katz result; however, that would not work now since Guth-Katz is already out there for OpenAI to see. Perhaps OpenAI should try to improve Guth-Katz. 


6) In the short term, this result and what it portends, is good: math problems we care about will be resolved with the help of AI, perhaps solely by AI. But in the long run we may lose the ability---or at least the patience---to do the proofs ourselves. Note that I am assuming that AI will have future successes---see item 10-ONE for a counterthought.

7) AI seems to be good at combining known concepts. Is it good at coming up with new ones? Are humans? The distinction between combining known ideas and coming up with new ones is very thin.

8) Two contrary lessons:

a) You should know many fields of mathematics so that you can use ideas from one field in another, like the AI did.

b) You should know some field of math really well so you may do something new in it that current AI could not have done.

9) If an AI produces a new treatment for cancer that is cheaper and better than what is known I do not think we will care that an AI did it (though we will have humans check it). Is mathematics similar? Do we care that an AI did it?  Medicine primarily values outcomes; Mathematics also values understanding. Does reading a proof that AI did give the same understanding as coming up with it yourself?  Can AI help with that as well?

10) I suggest two futures:

ONE: While this AI-generated (or AI-assisted) result is impressive, it will be a rare occurrence. This result was actually a counterexample. The needed math was known. The result was interesting. This is a perfect storm that we might not see again for a while.

TWO: Even before the AI revolution, when I came up with a math problem I wanted solved, I would seek help, perhaps too early. My curiosity far exceeds my ego.  Since AI makes it easy to get help, my fear is that eventually we will all be Bill Gasarch---scary.

By gasarch

Let $S\subseteq {\mathbb F}_2^u$ have size $n=2^\ell$, and let $h:{\mathbb F}_2^u\to {\mathbb F}_2^\ell$ be a uniformly random linear map. For $y\in{\mathbb F}_2^\ell$, write ${load}_h(y):=|h^{-1}(y)\cap S|$, and let $M(S,h):=\max_{y\in{\mathbb F}_2^\ell}\{load}_h(y)$ be the maximum load. Jaber, Kumar and Zuckerman (STOC 2025) proved that the expected maximum load of $h$ on $S$ is at most $16\log n/\log\log n$, matching the fully independent keys-into-bins scale up to constants. Their proof also gives the tail estimate \[ \Pr\left[ M(S,h)\ge R\frac{\log n}{\log\log n} \right] \le O\left(\frac{1}{R^{2}}\right). \] We record a base optimization in their exponential-potential method showing that binary linear hashing nearly matches fully independent hashing also at the level of the second-order maximum-load scale. For every $R>1$ satisfying $R\ell^{1-1/R}\ge D\ln\ell$, where $D$ is an absolute constant, we prove \[ \Pr\left[ M(S,h)\ge R\frac{\log n}{\log\log n} \right] \le O\left( \frac{(\log\log n)^2}{R^2(\log n)^{2-2/R}} \right). \] Integrating this tail yields \[ {\mathbb E}[M(S,h)] \le \left( 1+ (1+o(1)) \frac{\log\log\log n}{\log\log n} \right) \frac{\log n}{\log\log n}. \] Thus binary linear hashing matches fully independent hashing in the leading term and matches the dominant second-order correction up to a $1+o(1)$ factor. We also prove, by an independent self-contained argument, a sharp tail bound for one prescribed bucket: for fixed $y\in{\mathbb F}_2^\ell$, \[ \Pr[{load}_h(y)>2^a-2]\le \gamma^{-1}2^{-a^2}, \] where $\gamma=\prod_{j\ge1}(1-2^{-j})$. A subspace construction shows that this is asymptotically tight even in the leading constant as $a\to\infty$. However, this controls only a fixed bucket; a direct union bound over all buckets loses a factor $2^\ell$.

We study the parallel complexity of computing the arboricity of a graph, defined as the minimum number of forests into which its edges can be partitioned. For graphs of bounded treewidth, we present a simple dynamic programming–based parallel algorithm that constructs an optimal partition of the edges into forests. For graphs of bounded genus, we give an alternative and simple parallel algorithm for computing arboricity by adapting Goldberg’s method for finding dense subgraphs.

On mathematics, machines, and what the proof never held

When I was young, I learned about the great Sanskrit poet and playwright Kālidāsa, the author of Śakuntalā and other works whose beauty has survived across centuries. But the story I remember most about him is about a man sitting on a tree branch and cutting the very branch on which he sits. It was usually told as a joke about stupidity, but I could never hear it only that way. The man was absorbed in the motion of the blade, unable to see the branch beneath him. He was not failing at the task. He was doing exactly what he had set out to do, letting the task fill the whole field of attention.

Mathematics has always needed proof. Without it, a claim remains too dependent on the person who made it. Proof allows an insight to be checked by others, long after the circumstances of its discovery have disappeared. It is one of the most beautiful inventions of human thought.

But I have begun to wonder whether, over the centuries, something else happened alongside this beauty. 

Full essay: https://nisheethvishnoi.substack.com/

By nisheethvishnoi

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 As mentioned in a previous post, Naoki Kobayashi will receive one of the two CONCUR 2026 Test-of-Time Awards at CONCUR 2026. Naoki has kindly agreed to answer some questions of mine on his award-winning paper via email. I am delighted to post his answers below and hope you'll enjoy reading them as much as I did. Thanks, Naoki!

Luca: You receive the CONCUR ToT Award 2026 for your paper  A New Type System for Deadlock-Free Processes, which appeared at CONCUR 2006. That article is the culmination of a series of contributions you gave on the development of type systems for variations on the pi-calculus that guarantee deadlock-freedom. Could you briefly explain to our readers how you came to study the question addressed in your award-winning article and how the main ideas in your CONCUR 2006 paper evolved over time? Which of the ideas and results in your paper did you find most pleasing, surprising or challenging? 

By Luca Aceto

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Paul Erdős’s, in his 1946  paper published in the American Mathematical Monthly, posed two general questions about the distribution of distances determined by a finite set of points in a metric space.

1. Unit Distance Problem: At most how many times can the same distance (say, distance 1) occur among a set of n points?

2. Distinct Distances Problem: What is the minimum number of distinct distances determined by a set of n points?

Erdős conjectured that in the plane the number of unit distances determined by n points is at most , for a positive constant c, but the best known upper bound, due to Spencer, Szemeredi, and Trotter is only .

As for the Distinct Distances Problem, the order of magnitude of the conjectured minimum is .  In 2010 a sensational paper of Guth and Katz presents a proof of an almost tight lower bound of the order of Janos Pach wrote about it in this 2010 post. See also this post from 2008, that explains (among other things) the proof for the upper bound.

I have just learned that an internal model of OpenAI have very recently disproved Erdős’ conjecture for the unit distance problem and found an example with more than unit distances. This is truly amazing. The construction relies on algebraic number theory.

Here is Open AI announcement and technical paper.

The proof is presented, explained and discussed in the paper Remarks on the disproof of the unit distance conjecture by Alon, Bloom, Gowers, Litt, Sawin, Shankar,Tsimerman, Wang, and Matchett Wood. (I learned about it from an answer to an MO question on the topic of mathematics and AI.)

Like the computer-based proof of the four color theorem in 1976 by Appel and Haken, this may well be a scientific landmark whose importance goes beyond combinatorics and beyond mathematics. I will add a link to the Open AI document when I will have it. (Done.)

There is also a short Open AI video where the result is presented by Tim Gowers and by four members of the team, Lijie Chen, Mark Sellke, Mehtaab Sawhney, and Sebastien (Seb) Bubeck.

Update: Will Sawin proved a lower bound of ; This was further improved to ;  There are interesting comments on the ErdosProblems site; The list of best constants so far can be found in Terence Tao’s Github. The result is reported and discussed on the Geomblog; computational complexity; An interesting commentary by Erik Hoel.

By Gil Kalai

 OpenAI just announced that ChatGPT has disproved a conjecture about one of Erdos's most famous problems: the unit distance problem.

This problem is personal to me: I spent a good chunk of time during my Ph.D mulling over it, and it's what hooked me into computational geometry. Like most of Erdos's problems, it's really easy to state

Let P be a set of n points in the plane (amen). What is the maximum number of unit distances that can be achieved? 

(the amen is a running joke in my old field of computational geometry) 

Note that this is really about duplicate distances (because if you get a bunch of pairs of points at distance d, you can scale the point set so that d = 1). It's also trivial to see that the maximum is at least n-1 (just put points evenly spaced along the number line), and that the number can't be more than n-choose-2 (because that's the number of pairs). 

So what's the real number? Erdos showed using a fairly complicated construction that you can get a set of points that has $n^{1 + 1/\log\log n}$ unit distances. On the other side of it, a famous result from 1983 by Spencer, Szemederi and Trotter showed that you can't get more than $O(n^{4/3})$ distances. 

Erdos himself used a really elegant but weaker argument to show that you can't get more than $O(n^{3/2})$ distances. And the argument was cool and deceptive (in retrospect). To get a distance pair of 1, a circle of size 1 around a point must touch another point (and vice versa). Draw an edge between those two points when this happens. So here's a fun fact: you can't create a situation where two points are connected by edges to each of three other points. Or to be more formal, you can't create a situation where there's a $K_{2,3}$ bipartite graph hidden inside the set of edges. By a well known result in graph theory this means this graph can't have too many edges in it (because if it did you'd eventually find one of these special graphs): specifically no more than $O(n^{3/2})$ edges. 

So there's a limit. But what's the real limit? A long standing conjecture was that you could NOT get anything nontrivially more than n pairs. Specifically that you couldn't get $\Omega(n^{1 + \epsilon})$ pairs for any $\epsilon$. This is frustrating because the gap between this, and $n^{4/3}$ is huge. 

Turns out this conjecture was wrong. And ChatGPT proved it, by building a complicated generalization of Erdos's construction that is indeed of size $\Omega(n^{1 + \epsilon})$ for some $\epsilon > 0$. 

This was a tantalizing, infuriating, and beautiful problem that has resisted progress for a very long time, and touches on some very deep concepts in mathematics. It's really impressive that an AI system has provided a proof for it. For more on the significance of the result and some interpretation of the proof technique, check out the companion article. 

By Suresh Venkatasubramanian