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We study two positional games where two players take turns picking a
previously unpicked vertex of a hypergraph $H$. We say a player fills an edge
of $H$ if that player has picked all the vertices of that edge. In the
Maker-Maker game, whoever first fills an edge wins, or we get a draw if no edge
is filled. In the Maker-Breaker game, the first player aims at filling an edge
while the second player aims at preventing the first player from filling an
edge. We show that, for both games, deciding whether the first player has a
winning strategy is a PSPACE-complete problem even when restricted to 4-uniform
hypergraphs. For the Maker-Maker game, this improves on a previous result for
hypergraphs of rank 4. For the Maker-Breaker game, this improves on a previous
result for 5-uniform hypergraphs, and closes the complexity gap as the problem
for hypergraphs of rank 3 is known to be solvable in polynomial time.
We study two positional games where two players take turns picking a
previously unpicked vertex of a hypergraph $H$. We say a player fills an edge
of $H$ if that player has picked all the vertices of that edge. In the
Maker-Maker game, whoever first fills an edge wins, or we get a draw if no edge
is filled. In the Maker-Breaker game, the first player aims at filling an edge
while the second player aims at preventing the first player from filling an
edge. We show that, for both games, deciding whether the first player has a
winning strategy is a PSPACE-complete problem even when restricted to 4-uniform
hypergraphs. For the Maker-Maker game, this improves on a previous result for
hypergraphs of rank 4. For the Maker-Breaker game, this improves on a previous
result for 5-uniform hypergraphs, and closes the complexity gap as the problem
for hypergraphs of rank 3 is known to be solvable in polynomial time.
The Berry phase is a fundamental quantity in the classification of
topological phases of matter. In this paper, we present a new quantum algorithm
and several complexity-theoretical results for the Berry phase estimation (BPE)
problems. Our new quantum algorithm achieves BPE in a more general setting than
previously known quantum algorithms, with a theoretical guarantee. For the
complexity-theoretic results, we consider three cases. First, we prove
$\mathsf{BQP}$-completeness when we are given a guiding state that has a large
overlap with the ground state. This result establishes an exponential quantum
speedup for estimating the Berry phase. Second, we prove
$\mathsf{dUQMA}$-completeness when we have \textit{a priori} bound for ground
state energy. Here, $\mathsf{dUQMA}$ is a variant of the unique witness version
of $\mathsf{QMA}$ (i.e., $\mathsf{UQMA}$), which we introduce in this paper,
and this class precisely captures the complexity of BPE without the known
guiding state. Remarkably, this problem turned out to be the first natural
problem contained in both $\mathsf{UQMA}$ and $\mathsf{co}$-$\mathsf{UQMA}$.
Third, we show $\mathsf{P}^{\mathsf{dUQMA[log]}}$-hardness and containment in
$\mathsf{P}^{\mathsf{PGQMA[log]}}$ when we have no additional assumption. These
results advance the role of quantum computing in the study of topological
phases of matter and provide a pathway for clarifying the connection between
topological phases of matter and computational complexity.
The Berry phase is a fundamental quantity in the classification of
topological phases of matter. In this paper, we present a new quantum algorithm
and several complexity-theoretical results for the Berry phase estimation (BPE)
problems. Our new quantum algorithm achieves BPE in a more general setting than
previously known quantum algorithms, with a theoretical guarantee. For the
complexity-theoretic results, we consider three cases. First, we prove
$\mathsf{BQP}$-completeness when we are given a guiding state that has a large
overlap with the ground state. This result establishes an exponential quantum
speedup for estimating the Berry phase. Second, we prove
$\mathsf{dUQMA}$-completeness when we have \textit{a priori} bound for ground
state energy. Here, $\mathsf{dUQMA}$ is a variant of the unique witness version
of $\mathsf{QMA}$ (i.e., $\mathsf{UQMA}$), which we introduce in this paper,
and this class precisely captures the complexity of BPE without the known
guiding state. Remarkably, this problem turned out to be the first natural
problem contained in both $\mathsf{UQMA}$ and $\mathsf{co}$-$\mathsf{UQMA}$.
Third, we show $\mathsf{P}^{\mathsf{dUQMA[log]}}$-hardness and containment in
$\mathsf{P}^{\mathsf{PGQMA[log]}}$ when we have no additional assumption. These
results advance the role of quantum computing in the study of topological
phases of matter and provide a pathway for clarifying the connection between
topological phases of matter and computational complexity.
Authors: Mikhail Goncharov, Alexander S. Kulikov, Georgie Levtsov
Bit addition arises virtually everywhere in digital circuits: arithmetic
operations, increment/decrement operators, computing addresses and table
indices, and so on. Since bit addition is such a basic task in Boolean circuit
synthesis, a lot of research has been done on constructing efficient circuits
for various special cases of it. A vast majority of these results are devoted
to optimizing the circuit depth (also known as delay).
In this paper, we investigate the circuit size (also known as area) over the
full binary basis of bit addition. Though most of the known circuits are built
from Half Adders and Full Adders, we show that, in many interesting scenarios,
these circuits have suboptimal size. Namely, we improve an upper bound $5n-3m$
to $4.5n-2m$, where $n$ is the number of input bits and $m$ is the number of
output bits. In the regimes where $m$ is small compared to $n$ (for example,
for computing the sum of $n$ bits or multiplying two $n$-bit integers), this
leads to $10\%$ improvement.
We complement our theoretical result by an open-source implementation of
generators producing circuits for bit addition and multiplication. The
generators allow one to produce the corresponding circuits in two lines of code
and to compare them to existing designs.
Bit addition arises virtually everywhere in digital circuits: arithmetic
operations, increment/decrement operators, computing addresses and table
indices, and so on. Since bit addition is such a basic task in Boolean circuit
synthesis, a lot of research has been done on constructing efficient circuits
for various special cases of it. A vast majority of these results are devoted
to optimizing the circuit depth (also known as delay).
In this paper, we investigate the circuit size (also known as area) over the
full binary basis of bit addition. Though most of the known circuits are built
from Half Adders and Full Adders, we show that, in many interesting scenarios,
these circuits have suboptimal size. Namely, we improve an upper bound $5n-3m$
to $4.5n-2m$, where $n$ is the number of input bits and $m$ is the number of
output bits. In the regimes where $m$ is small compared to $n$ (for example,
for computing the sum of $n$ bits or multiplying two $n$-bit integers), this
leads to $10\%$ improvement.
We complement our theoretical result by an open-source implementation of
generators producing circuits for bit addition and multiplication. The
generators allow one to produce the corresponding circuits in two lines of code
and to compare them to existing designs.
The k-core of a graph is its maximal subgraph with minimum degree at least k,
and the core value of a vertex u is the largest k for which u is contained in
the k-core of the graph. Among cohesive subgraphs, k-core and its variants have
received a lot of attention recently, particularly on dynamic graphs, as
reported by Hanauer, Henzinger, and Schulz in their recent survey on dynamic
graph algorithms. We answer questions on k-core stated in the survey, proving
that there is no efficient dynamic algorithm for k-core or to find (2 -
{\epsilon})-approximations for the core values, unless we can improve
decade-long state-of-the-art algorithms in many areas including matrix
multiplication and satisfiability, based on the established OMv and SETH
conjectures. Some of our results show that there is no dynamic algorithm for
k-core asymptotically faster than the trivial ones. This explains why most
recent research papers in this area focus not on a generic efficient dynamic
algorithm, but on finding a bounded algorithm, which is fast when few core
values change per update. However, we also prove that such bounded algorithms
do not exist, based on the OMv conjecture. We present lower bounds also for a
directed version of the problem, and for the edge variant of the problem, known
as k-truss. On the positive side, we present a polylogarithmic dynamic
algorithm for 2-core.
The k-core of a graph is its maximal subgraph with minimum degree at least k,
and the core value of a vertex u is the largest k for which u is contained in
the k-core of the graph. Among cohesive subgraphs, k-core and its variants have
received a lot of attention recently, particularly on dynamic graphs, as
reported by Hanauer, Henzinger, and Schulz in their recent survey on dynamic
graph algorithms. We answer questions on k-core stated in the survey, proving
that there is no efficient dynamic algorithm for k-core or to find (2 -
{\epsilon})-approximations for the core values, unless we can improve
decade-long state-of-the-art algorithms in many areas including matrix
multiplication and satisfiability, based on the established OMv and SETH
conjectures. Some of our results show that there is no dynamic algorithm for
k-core asymptotically faster than the trivial ones. This explains why most
recent research papers in this area focus not on a generic efficient dynamic
algorithm, but on finding a bounded algorithm, which is fast when few core
values change per update. However, we also prove that such bounded algorithms
do not exist, based on the OMv conjecture. We present lower bounds also for a
directed version of the problem, and for the edge variant of the problem, known
as k-truss. On the positive side, we present a polylogarithmic dynamic
algorithm for 2-core.
Authors: Zheng Luo, Wim Van den Broeck, Guy Van den Broeck, Yisu Remy Wang
Most research on query optimization has centered on binary join algorithms
like hash join and sort-merge join. However, recent years have seen growing
interest in theoretically optimal algorithms, notably Yannakakis' algorithm.
These algorithms rely on join trees, which differ from the operator trees for
binary joins and require new optimization techniques. We propose three
approaches to constructing join trees for acyclic queries. First, we give an
algorithm to enumerate all join trees of an alpha-acyclic query by edits with
amortized constant delay, which forms the basis of a cost-based optimizer for
acyclic joins. Second, we show that the Maximum Cardinality Search algorithm by
Tarjan and Yannakakis constructs a unique shallowest join tree, rooted at any
relation, for a Berge-acyclic query; this tree enables parallel execution of
large join queries. Finally, we prove that any connected left-deep linear plan
for a gamma-acyclic query can be converted into a join tree by a simple
algorithm, allowing reuse of optimization infrastructure developed for binary
joins.
Most research on query optimization has centered on binary join algorithms
like hash join and sort-merge join. However, recent years have seen growing
interest in theoretically optimal algorithms, notably Yannakakis' algorithm.
These algorithms rely on join trees, which differ from the operator trees for
binary joins and require new optimization techniques. We propose three
approaches to constructing join trees for acyclic queries. First, we give an
algorithm to enumerate all join trees of an alpha-acyclic query by edits with
amortized constant delay, which forms the basis of a cost-based optimizer for
acyclic joins. Second, we show that the Maximum Cardinality Search algorithm by
Tarjan and Yannakakis constructs a unique shallowest join tree, rooted at any
relation, for a Berge-acyclic query; this tree enables parallel execution of
large join queries. Finally, we prove that any connected left-deep linear plan
for a gamma-acyclic query can be converted into a join tree by a simple
algorithm, allowing reuse of optimization infrastructure developed for binary
joins.
We initiate a study of solving a row/column diagonally dominant (RDD/CDD)
linear system $Mx=b$ in sublinear time, with the goal of estimating
$t^{\top}x^*$ for a given vector $t\in R^n$ and a specific solution $x^*$. This
setting naturally generalizes the study of sublinear-time solvers for symmetric
diagonally dominant (SDD) systems [AKP19] to the asymmetric case.
Our first contributions are characterizations of the problem's mathematical
structure. We express a solution $x^*$ via a Neumann series, prove its
convergence, and upper bound the truncation error on this series through a
novel quantity of $M$, termed the maximum $p$-norm gap. This quantity
generalizes the spectral gap of symmetric matrices and captures how the
structure of $M$ governs the problem's computational difficulty.
For systems with bounded maximum $p$-norm gap, we develop a collection of
algorithmic results for locally approximating $t^{\top}x^*$ under various
scenarios and error measures. We derive these results by adapting the
techniques of random-walk sampling, local push, and their bidirectional
combination, which have proved powerful for special cases of solving RDD/CDD
systems, particularly estimating PageRank and effective resistance on graphs.
Our general framework yields deeper insights, extended results, and improved
complexity bounds for these problems. Notably, our perspective provides a
unified understanding of Forward Push and Backward Push, two fundamental
approaches for estimating random-walk probabilities on graphs.
Our framework also inherits the hardness results for sublinear-time SDD
solvers and local PageRank computation, establishing lower bounds on the
maximum $p$-norm gap or the accuracy parameter. We hope that our work opens the
door for further study into sublinear solvers, local graph algorithms, and
directed spectral graph theory.
We initiate a study of solving a row/column diagonally dominant (RDD/CDD)
linear system $Mx=b$ in sublinear time, with the goal of estimating
$t^{\top}x^*$ for a given vector $t\in R^n$ and a specific solution $x^*$. This
setting naturally generalizes the study of sublinear-time solvers for symmetric
diagonally dominant (SDD) systems [AKP19] to the asymmetric case.
Our first contributions are characterizations of the problem's mathematical
structure. We express a solution $x^*$ via a Neumann series, prove its
convergence, and upper bound the truncation error on this series through a
novel quantity of $M$, termed the maximum $p$-norm gap. This quantity
generalizes the spectral gap of symmetric matrices and captures how the
structure of $M$ governs the problem's computational difficulty.
For systems with bounded maximum $p$-norm gap, we develop a collection of
algorithmic results for locally approximating $t^{\top}x^*$ under various
scenarios and error measures. We derive these results by adapting the
techniques of random-walk sampling, local push, and their bidirectional
combination, which have proved powerful for special cases of solving RDD/CDD
systems, particularly estimating PageRank and effective resistance on graphs.
Our general framework yields deeper insights, extended results, and improved
complexity bounds for these problems. Notably, our perspective provides a
unified understanding of Forward Push and Backward Push, two fundamental
approaches for estimating random-walk probabilities on graphs.
Our framework also inherits the hardness results for sublinear-time SDD
solvers and local PageRank computation, establishing lower bounds on the
maximum $p$-norm gap or the accuracy parameter. We hope that our work opens the
door for further study into sublinear solvers, local graph algorithms, and
directed spectral graph theory.
Efficient routing is critical for payment channel networks (PCNs) such as the
Lightning Network (LN), where most clients currently rely on Dijkstra-based
algorithms for payment pathfinding. While Dijkstra's algorithm has long been
regarded as optimal on sparse graphs, recent theoretical work challenges this
view. The new Bounded Multi-Source Shortest Path (BMSSP) algorithm by Duan et
al. theoretically achieves $O(m~log^{2/3}~n)$ runtime, which is asymptotically
faster than Dijkstra's $O(m + n~log~n)$ on sparse directed graphs. In this
paper, we implement BMSSP on Rust and compare its performance against
Dijkstra's using real LN topology data. Our evaluation, based on multiple
randomized trials and statistical tests, shows that current implementations of
BMSSP do not significantly outperform Dijkstra's in practice, and speedups are
smaller than what theory predicts, possibly due to implementation and constant
factor overheads. These results provide the first empirical evidence of BMSSP's
potential to accelerate LN routing and inform future optimizations of PCN
pathfinding algorithms.
Efficient routing is critical for payment channel networks (PCNs) such as the
Lightning Network (LN), where most clients currently rely on Dijkstra-based
algorithms for payment pathfinding. While Dijkstra's algorithm has long been
regarded as optimal on sparse graphs, recent theoretical work challenges this
view. The new Bounded Multi-Source Shortest Path (BMSSP) algorithm by Duan et
al. theoretically achieves $O(m~log^{2/3}~n)$ runtime, which is asymptotically
faster than Dijkstra's $O(m + n~log~n)$ on sparse directed graphs. In this
paper, we implement BMSSP on Rust and compare its performance against
Dijkstra's using real LN topology data. Our evaluation, based on multiple
randomized trials and statistical tests, shows that current implementations of
BMSSP do not significantly outperform Dijkstra's in practice, and speedups are
smaller than what theory predicts, possibly due to implementation and constant
factor overheads. These results provide the first empirical evidence of BMSSP's
potential to accelerate LN routing and inform future optimizations of PCN
pathfinding algorithms.
Polynomial bounds for the Chowla cosine problem were achieved independently in two very recent works. Zhihan Jin, Aleksa Milojević, István Tomon, Shengtong Zhang: From small eigenvalues to large cuts, and Chowla’s cosine problem; Benjamin Bedert: Polynomial bounds for the Chowla Cosine Problem Abstract … Continue reading →
Polynomial bounds for the Chowla cosine problem were achieved independently in two very recent works.
Abstract (JMTZ’s paper): We show that there exists an absolute constant such that for every we have
This gives the first polynomial bound for Chowla’s cosine problem from 1965.
To show this, we prove structural statements about graphs whose smallest eigenvalue is small in absolute value. As another application, we show that any graph with edges and no clique of size has a cut of size at least for some . This proves a weak version of a celebrated conjecture of Alon, Bollob’as, Krivelevich, and Sudakov.
Our proofs are based on novel spectral and linear algebraic techniques, involving subspace compressions and Hadamard products of matrices.
Abstract (Bedert’s paper): Let be a finite set of positive integers, and consider the cosine sum . We prove that there exists an absolute constant such that
establishing polynomial bounds for the Chowla cosine problem.
These new breakthroughs look wonderful and further commentary in the comment section is very welcome. Chowla conjectured that is the answer.
History. Both papers gives the interesting history of the problem. In 1948 Ankeny and Chowla asked if for every large enough set and some the some of cosines is smaller than for arbitrary large real . This was solved by M. Uchiyama and S. Uchiyama in 1960. In 1965 Sarvadaman Chowla asked if putting , can be taken as . Achieving followed from the resolution of a well-known problem by Littlewood and breaking the barrier was achieved by Bourgain and greatly improved by Rusza to .
Spectral graph theory. The paper by Jin, Milojević, Tomon, and Zhang reduces the problem to a question in spectral graph theory. The authors also prove a weak version of another conjecture in spectral graph theory by Alon, Bollobás, Krivelevich, and Sudakov.
Sum-free subsets of sets of integers. Benjamin Bedert recently solved a well-known question in additive combinatorics about sum free subsets of sets of integers his work is related to the same Littlewood problem mentioned above, and to a work by Bourgain. The interesting story behind it was told in a Quanta Magazine article by Leila Sloman.
h/t Nati Linial. I did not know about the problem (although it is problem #81 on Green’s 100 problems list), but Nati wrote me: “In ancient times when I thought about KKL, I used to read everything in the library about Harmonic analysis and I came across this conjecture.”
October 10-12, 2025 Pittsburgh, PA sites.google.com/andrew.cmu.edu/acorn-2025/home Carnegie Mellon University will be hosting the 2025 ACORN (Algorithms, Combinatorics, and Optimization Research Network) Workshop, October 10-12, 2025. Registration is now open at the website here: sites.google.com/andrew.cmu.edu/acorn-2025/home ACORN (Algorithms, Combinatorics, and Optimization Research Network) is a group of institutions, departments, and researchers committed to the principle that the … Continue reading ACORN Workshop at Carnegie Mellon University
By shacharlovett
October 10-12, 2025 Pittsburgh, PA https://sites.google.com/andrew.cmu.edu/acorn-2025/home Carnegie Mellon University will be hosting the 2025 ACORN (Algorithms, Combinatorics, and Optimization Research Network) Workshop, October 10-12, 2025. Registration is now open at the website here: https://sites.google.com/andrew.cmu.edu/acorn-2025/home ACORN (Algorithms, Combinatorics, and Optimization Research Network) is a group of institutions, departments, and researchers committed to the principle that the … Continue reading ACORN Workshop at Carnegie Mellon University
When announcing Open-AI's latest release last month, Sam Altman said "GPT-5 is the first time that it really feels like talking to an expert in any topic, like a PhD-level expert." Before we discuss whether GPT-5 got there, what does "PhD-Level intelligence" even mean?
We could just dismiss the idea but I'd rather try to formulate a reasonable definition, which I would expect from a good PhD student. It's not about knowing stuff, which we can always look up, but the ability to talk and engage about current research. Here is my suggestion.
The ability to understand a (well-presented) research paper or talk in the field.
The word "field" has narrowed over time as knowledge has become more specialized, but since the claim is that GPT-5 is an expert over all fields, that doesn't matter. The word "understand" causes more problems, it is hard to define for humans let alone machines.
In many PhD programs, there's an oral exam where we have previously given the candidate a list of research papers and they are expected to answer questions about these papers. If we claim a LLM has "PhD-level" knowledge, I'd expect the LLM to pass this test.
Does GPT-5 get there? I did an experiment with two recent papers, one showing Dijkstra's algorithm was optimal and another showing Dijkstra is not optimal. I used the GPT 5 Thinking model and GPT 5 Pro on the last question about new directions. A little more technical answers than I would have liked but it would likely have passed the oral exam. A good PhD student may work harder to get a more intuitive idea of the paper in order to understand it, and later on extend it.
You could ask for far more--getting a PhD requires significant original research, and LLMs for the most part haven't gotten there (yet). I've not had luck getting any large-language model to make real progress on open questions and haven't seen many successful examples from other people trying to do the same.
So while large-language models might have PhD-level expertise they can't replace PhD students who actually do the research.
By Lance Fortnow
When announcing Open-AI's latest release last month, Sam Altman said "GPT-5 is the first time that it really feels like talking to an expert in any topic, like a PhD-level expert." Before we discuss whether GPT-5 got there, what does "PhD-Level intelligence" even mean?
We could just dismiss the idea but I'd rather try to formulate a reasonable definition, which I would expect from a good PhD student. It's not about knowing stuff, which we can always look up, but the ability to talk and engage about current research. Here is my suggestion.
The ability to understand a (well-presented) research paper or talk in the field.
The word "field" has narrowed over time as knowledge has become more specialized, but since the claim is that GPT-5 is an expert over all fields, that doesn't matter. The word "understand" causes more problems, it is hard to define for humans let alone machines.
In many PhD programs, there's an oral exam where we have previously given the candidate a list of research papers and they are expected to answer questions about these papers. If we claim a LLM has "PhD-level" knowledge, I'd expect the LLM to pass this test.
Does GPT-5 get there? I did an experiment with two recent papers, one showing Dijkstra's algorithm was optimal and another showing Dijkstra is not optimal. I used the GPT 5 Thinking model and GPT 5 Pro on the last question about new directions. A little more technical answers than I would have liked but it would likely have passed the oral exam. A good PhD student may work harder to get a more intuitive idea of the paper in order to understand it, and later on extend it.
You could ask for far more--getting a PhD requires significant original research, and LLMs for the most part haven't gotten there (yet). I've not had luck getting any large-language model to make real progress on open questions and haven't seen many successful examples from other people trying to do the same.
So while large-language models might have PhD-level expertise they can't replace PhD students who actually do the research.
The complexity of representing a polynomial by a Read-Once Oblivious
Algebraic Branching Program (ROABP) is highly dependent on the chosen variable
ordering. Bhargava et al. prove that finding the optimal ordering is NP-hard,
and provide some evidence (based on the Small Set Expansion hypothesis) that it
is also hard to approximate the optimal ROABP width. In another work, Baraskar
et al. show that it is NP-hard to test whether a polynomial is in the
$\mathrm{GL}_n$ orbit of a polynomial of sparsity at most $s$. Building upon
these works, we show the following results: first, we prove that approximating
the minimum ROABP width up to any constant factor is NP-hard, when the input is
presented as a circuit. This removes the reliance on stronger conjectures in
the previous work. Second, we show that testing if an input polynomial given in
the sparse representation is in the affine $\mathrm{GL}_n$ orbit of a width-$w$
ROABP is NP-hard. Furthermore, we show that over fields of characteristic $0$,
the problem is NP-hard even when the input polynomial is homogeneous. This
provides the first NP-hardness results for membership testing for a dense
subclass of polynomial sized algebraic branching programs (VBP). Finally, we
locate the source of hardness for the order finding problem at the lowest
possible non-trivial degree, proving that the problem is NP-hard even for
quadratic forms.
The complexity of representing a polynomial by a Read-Once Oblivious
Algebraic Branching Program (ROABP) is highly dependent on the chosen variable
ordering. Bhargava et al. prove that finding the optimal ordering is NP-hard,
and provide some evidence (based on the Small Set Expansion hypothesis) that it
is also hard to approximate the optimal ROABP width. In another work, Baraskar
et al. show that it is NP-hard to test whether a polynomial is in the
$\mathrm{GL}_n$ orbit of a polynomial of sparsity at most $s$. Building upon
these works, we show the following results: first, we prove that approximating
the minimum ROABP width up to any constant factor is NP-hard, when the input is
presented as a circuit. This removes the reliance on stronger conjectures in
the previous work. Second, we show that testing if an input polynomial given in
the sparse representation is in the affine $\mathrm{GL}_n$ orbit of a width-$w$
ROABP is NP-hard. Furthermore, we show that over fields of characteristic $0$,
the problem is NP-hard even when the input polynomial is homogeneous. This
provides the first NP-hardness results for membership testing for a dense
subclass of polynomial sized algebraic branching programs (VBP). Finally, we
locate the source of hardness for the order finding problem at the lowest
possible non-trivial degree, proving that the problem is NP-hard even for
quadratic forms.
Designing a deterministic polynomial time algorithm for factoring univariate
polynomials over finite fields remains a notorious open problem. In this paper,
we present an unconditional deterministic algorithm that takes as input an
irreducible polynomial $f \in \mathbb{Z}[x]$, and computes the factorisation of
its reductions modulo $p$ for all primes $p$ up to a prescribed bound $N$. The
\emph{average running time per prime} is polynomial in the size of the input
and the degree of the splitting field of $f$ over $\mathbb{Q}$. In particular,
if $f$ is Galois, we succeed in factoring in (amortised) deterministic
polynomial time.
Designing a deterministic polynomial time algorithm for factoring univariate
polynomials over finite fields remains a notorious open problem. In this paper,
we present an unconditional deterministic algorithm that takes as input an
irreducible polynomial $f \in \mathbb{Z}[x]$, and computes the factorisation of
its reductions modulo $p$ for all primes $p$ up to a prescribed bound $N$. The
\emph{average running time per prime} is polynomial in the size of the input
and the degree of the splitting field of $f$ over $\mathbb{Q}$. In particular,
if $f$ is Galois, we succeed in factoring in (amortised) deterministic
polynomial time.
Authors: Shannon Cheng, Anna Chlopecki, Saarah Nazar, Eric Samperton
We give a new, elementary proof of what we believe is the simplest known
example of a ``natural'' problem in computational 3-dimensional topology that
is $\mathsf{NP}$-hard -- namely, the \emph{Trivial Sublink Problem}: given a
diagram $L$ of a link in $S^3$ and a positive integer $k$, decide if $L$
contains a $k$ component sublink that is trivial. This problem was previously
shown to be $\mathsf{NP}$-hard in independent works of Koenig-Tsvietkova and de
Mesmay-Rieck-Sedgwick-Tancer, both of which used reductions from
$\mathsf{3SAT}$. The reduction we describe instead starts with the Independent
Set Problem, and allows us to avoid the use of Brunnian links such as the
Borromean rings. On the technical level, this entails a new conceptual insight:
the Trivial Sublink Problem is hard entirely due to mod 2 pairwise linking,
with no need for integral or higher order linking. On the pedagogical level,
the reduction we describe is entirely elementary, and thus suitable for
introducing undergraduates and non-experts to complexity-theoretic
low-dimensional topology. To drive this point home, in this work we assume no
familiarity with low-dimensional topology, and -- other than Reidemeister's
Theorem and Karp's result that the Clique Problem is $\mathsf{NP}$-hard -- we
provide more-or-less complete definitions and proofs. We have also constructed
a web app that accompanies this work and allows a user to visualize the new
reduction interactively.
We give a new, elementary proof of what we believe is the simplest known
example of a ``natural'' problem in computational 3-dimensional topology that
is $\mathsf{NP}$-hard -- namely, the \emph{Trivial Sublink Problem}: given a
diagram $L$ of a link in $S^3$ and a positive integer $k$, decide if $L$
contains a $k$ component sublink that is trivial. This problem was previously
shown to be $\mathsf{NP}$-hard in independent works of Koenig-Tsvietkova and de
Mesmay-Rieck-Sedgwick-Tancer, both of which used reductions from
$\mathsf{3SAT}$. The reduction we describe instead starts with the Independent
Set Problem, and allows us to avoid the use of Brunnian links such as the
Borromean rings. On the technical level, this entails a new conceptual insight:
the Trivial Sublink Problem is hard entirely due to mod 2 pairwise linking,
with no need for integral or higher order linking. On the pedagogical level,
the reduction we describe is entirely elementary, and thus suitable for
introducing undergraduates and non-experts to complexity-theoretic
low-dimensional topology. To drive this point home, in this work we assume no
familiarity with low-dimensional topology, and -- other than Reidemeister's
Theorem and Karp's result that the Clique Problem is $\mathsf{NP}$-hard -- we
provide more-or-less complete definitions and proofs. We have also constructed
a web app that accompanies this work and allows a user to visualize the new
reduction interactively.
Let $S$ be a set of $n$ points in the Euclidean plane and general position
i.e., no three points are collinear. An \emph{at most $k$-out polygon of $S$}
is a simple polygon such that each vertex is a point in $S$ and there are at
most $k$ points outside the polygon. In this paper, we consider the problem of
enumerating all the at most $k$-out polygon of $S$. We propose a new
enumeration algorithm for the at most $k$-out polygons of a point set. Our
algorithm enumerates all the at most $k$-out polygons in $\mathcal{O}(n^2
\log{n})$ delay, while the running time of an existing algorithm is
$\mathcal{O}(n^3 \log{n})$ delay.
Let $S$ be a set of $n$ points in the Euclidean plane and general position
i.e., no three points are collinear. An \emph{at most $k$-out polygon of $S$}
is a simple polygon such that each vertex is a point in $S$ and there are at
most $k$ points outside the polygon. In this paper, we consider the problem of
enumerating all the at most $k$-out polygon of $S$. We propose a new
enumeration algorithm for the at most $k$-out polygons of a point set. Our
algorithm enumerates all the at most $k$-out polygons in $\mathcal{O}(n^2
\log{n})$ delay, while the running time of an existing algorithm is
$\mathcal{O}(n^3 \log{n})$ delay.
We study sublinear-time algorithms for solving linear systems $Sz = b$, where
$S$ is a diagonally dominant matrix, i.e., $|S_{ii}| \geq \delta + \sum_{j \ne
i} |S_{ij}|$ for all $i \in [n]$, for some $\delta \geq 0$. We present
randomized algorithms that, for any $u \in [n]$, return an estimate $z_u$ of
$z^*_u$ with additive error $\varepsilon$ or $\varepsilon \lVert
z^*\rVert_\infty$, where $z^*$ is some solution to $Sz^* = b$, and the
algorithm only needs to read a small portion of the input $S$ and $b$. For
example, when the additive error is $\varepsilon$ and assuming $\delta>0$, we
give an algorithm that runs in time $O\left( \frac{\|b\|_\infty^2
S_{\max}}{\delta^3 \varepsilon^2} \log \frac{\| b \|_\infty}{\delta
\varepsilon} \right)$, where $S_{\max} = \max_{i \in [n]} |S_{ii}|$. We also
prove a matching lower bound, showing that the linear dependence on $S_{\max}$
is optimal. Unlike previous sublinear-time algorithms, which apply only to
symmetric diagonally dominant matrices with non-negative diagonal entries, our
algorithm works for general strictly diagonally dominant matrices ($\delta >
0$) and a broader class of non-strictly diagonally dominant matrices $(\delta =
0)$. Our approach is based on analyzing a simple probabilistic recurrence
satisfied by the solution. As an application, we obtain an improved
sublinear-time algorithm for opinion estimation in the Friedkin--Johnsen model.
We study sublinear-time algorithms for solving linear systems $Sz = b$, where
$S$ is a diagonally dominant matrix, i.e., $|S_{ii}| \geq \delta + \sum_{j \ne
i} |S_{ij}|$ for all $i \in [n]$, for some $\delta \geq 0$. We present
randomized algorithms that, for any $u \in [n]$, return an estimate $z_u$ of
$z^*_u$ with additive error $\varepsilon$ or $\varepsilon \lVert
z^*\rVert_\infty$, where $z^*$ is some solution to $Sz^* = b$, and the
algorithm only needs to read a small portion of the input $S$ and $b$. For
example, when the additive error is $\varepsilon$ and assuming $\delta>0$, we
give an algorithm that runs in time $O\left( \frac{\|b\|_\infty^2
S_{\max}}{\delta^3 \varepsilon^2} \log \frac{\| b \|_\infty}{\delta
\varepsilon} \right)$, where $S_{\max} = \max_{i \in [n]} |S_{ii}|$. We also
prove a matching lower bound, showing that the linear dependence on $S_{\max}$
is optimal. Unlike previous sublinear-time algorithms, which apply only to
symmetric diagonally dominant matrices with non-negative diagonal entries, our
algorithm works for general strictly diagonally dominant matrices ($\delta >
0$) and a broader class of non-strictly diagonally dominant matrices $(\delta =
0)$. Our approach is based on analyzing a simple probabilistic recurrence
satisfied by the solution. As an application, we obtain an improved
sublinear-time algorithm for opinion estimation in the Friedkin--Johnsen model.
Authors: Pietro Armenante, Kai Huang, Nikhil Jha, Luca Vassio
Origin-Destination (OD) matrices are a core component of research on users'
mobility and summarize how individuals move between geographical regions. These
regions should be small enough to be representative of user mobility, without
incurring substantial privacy risks. There are two added values of the
NetMob2025 challenge dataset. Firstly, the data is extensive and contains a lot
of socio-demographic information that can be used to create multiple OD
matrices, based on the segments of the population. Secondly, a participant is
not merely a record in the data, but a statistically weighted proxy for a
segment of the real population. This opens the door to a fundamental shift in
the anonymization paradigm. A population-based view of privacy is central to
our contribution. By adjusting our anonymization framework to account for
representativeness, we are also protecting the inferred identity of the actual
population, rather than survey participants alone. The challenge addressed in
this work is to produce and compare OD matrices that are k-anonymous for survey
participants and for the whole population. We compare several traditional
methods of anonymization to k-anonymity by generalizing geographical areas.
These include generalization over a hierarchy (ATG and OIGH) and the classical
Mondrian. To this established toolkit, we add a novel method, i.e., ODkAnon, a
greedy algorithm aiming at balancing speed and quality. Unlike previous
approaches, which primarily address the privacy aspects of the given datasets,
we aim to contribute to the generation of privacy-preserving OD matrices
enriched with socio-demographic segmentation that achieves k-anonymity on the
actual population.
Origin-Destination (OD) matrices are a core component of research on users'
mobility and summarize how individuals move between geographical regions. These
regions should be small enough to be representative of user mobility, without
incurring substantial privacy risks. There are two added values of the
NetMob2025 challenge dataset. Firstly, the data is extensive and contains a lot
of socio-demographic information that can be used to create multiple OD
matrices, based on the segments of the population. Secondly, a participant is
not merely a record in the data, but a statistically weighted proxy for a
segment of the real population. This opens the door to a fundamental shift in
the anonymization paradigm. A population-based view of privacy is central to
our contribution. By adjusting our anonymization framework to account for
representativeness, we are also protecting the inferred identity of the actual
population, rather than survey participants alone. The challenge addressed in
this work is to produce and compare OD matrices that are k-anonymous for survey
participants and for the whole population. We compare several traditional
methods of anonymization to k-anonymity by generalizing geographical areas.
These include generalization over a hierarchy (ATG and OIGH) and the classical
Mondrian. To this established toolkit, we add a novel method, i.e., ODkAnon, a
greedy algorithm aiming at balancing speed and quality. Unlike previous
approaches, which primarily address the privacy aspects of the given datasets,
we aim to contribute to the generation of privacy-preserving OD matrices
enriched with socio-demographic segmentation that achieves k-anonymity on the
actual population.
Authors: Christian L. Hines, Samuel Spillard, Daniel P. Martin
TimeCluster is a visual analytics technique for discovering structure in long
multivariate time series by projecting overlapping windows of data into a
low-dimensional space. We show that, when Principal Component Analysis (PCA) is
chosen as the dimensionality reduction technique, this procedure is
mathematically equivalent to classical linear subspace identification
(block-Hankel matrix plus Singular Vector Decomposition (SVD)). In both
approaches, the same low-dimensional linear subspace is extracted from the time
series data. We first review the TimeCluster method and the theory of subspace
system identification. Then we show that forming the sliding-window matrix of a
time series yields a Hankel matrix, so applying PCA (via SVD) to this matrix
recovers the same principal directions as subspace identification. Thus the
cluster coordinates from TimeCluster coincide with the subspace identification
methods. We present experiments on synthetic and real dynamical signals
confirming that the two embeddings coincide. Finally, we explore and discuss
future opportunities enabled by this equivalence, including forecasting from
the identified state space, streaming/online extensions, incorporating and
visualising external inputs and robust techniques for displaying underlying
trends in corrupted data.
TimeCluster is a visual analytics technique for discovering structure in long
multivariate time series by projecting overlapping windows of data into a
low-dimensional space. We show that, when Principal Component Analysis (PCA) is
chosen as the dimensionality reduction technique, this procedure is
mathematically equivalent to classical linear subspace identification
(block-Hankel matrix plus Singular Vector Decomposition (SVD)). In both
approaches, the same low-dimensional linear subspace is extracted from the time
series data. We first review the TimeCluster method and the theory of subspace
system identification. Then we show that forming the sliding-window matrix of a
time series yields a Hankel matrix, so applying PCA (via SVD) to this matrix
recovers the same principal directions as subspace identification. Thus the
cluster coordinates from TimeCluster coincide with the subspace identification
methods. We present experiments on synthetic and real dynamical signals
confirming that the two embeddings coincide. Finally, we explore and discuss
future opportunities enabled by this equivalence, including forecasting from
the identified state space, streaming/online extensions, incorporating and
visualising external inputs and robust techniques for displaying underlying
trends in corrupted data.
In the $\ell$-Coloring Problem, we are given a graph on $n$ nodes, and tasked
with determining if its vertices can be properly colored using $\ell$ colors.
In this paper we study below-guarantee graph coloring, which tests whether an
$n$-vertex graph can be properly colored using $g-k$ colors, where $g$ is a
trivial upper bound such as $n$. We introduce an algorithmic framework that
builds on a packing of co-triangles $\overline{K_3}$ (independent sets of three
vertices): the algorithm greedily finds co-triangles and employs a win-win
analysis. If many are found, we immediately return YES; otherwise these
co-triangles form a small co-triangle modulator, whose deletion makes the graph
co-triangle-free.
Extending the work of [Gutin et al., SIDMA 2021], who solved $\ell$-Coloring
(for any $\ell$) in randomized $O^*(2^{k})$ time when given a
$\overline{K_2}$-free modulator of size $k$, we show that this problem can
likewise be solved in randomized $O^*(2^{k})$ time when given a
$\overline{K_3}$-free modulator of size~$k$.
This result in turn yields a randomized $O^{*}(2^{3k/2})$ algorithm for
$(n-k)$-Coloring (also known as Dual Coloring), improving the previous
$O^{*}(4^{k})$ bound. We then introduce a smaller parameterization,
$(\omega+\overline{\mu}-k)$-Coloring, where $\omega$ is the clique number and
$\overline{\mu}$ is the size of a maximum matching in the complement graph;
since $\omega+\overline{\mu}\le n$ for any graph, this problem is strictly
harder. Using the same co-triangle-packing argument, we obtain a randomized
$O^{*}(2^{6k})$ algorithm, establishing its fixed-parameter tractability for a
smaller parameter. Complementing this finding, we show that no fixed-parameter
tractable algorithm exists for $(\omega-k)$-Coloring or
$(\overline{\mu}-k)$-Coloring under standard complexity assumptions.
In the $\ell$-Coloring Problem, we are given a graph on $n$ nodes, and tasked
with determining if its vertices can be properly colored using $\ell$ colors.
In this paper we study below-guarantee graph coloring, which tests whether an
$n$-vertex graph can be properly colored using $g-k$ colors, where $g$ is a
trivial upper bound such as $n$. We introduce an algorithmic framework that
builds on a packing of co-triangles $\overline{K_3}$ (independent sets of three
vertices): the algorithm greedily finds co-triangles and employs a win-win
analysis. If many are found, we immediately return YES; otherwise these
co-triangles form a small co-triangle modulator, whose deletion makes the graph
co-triangle-free.
Extending the work of [Gutin et al., SIDMA 2021], who solved $\ell$-Coloring
(for any $\ell$) in randomized $O^*(2^{k})$ time when given a
$\overline{K_2}$-free modulator of size $k$, we show that this problem can
likewise be solved in randomized $O^*(2^{k})$ time when given a
$\overline{K_3}$-free modulator of size~$k$.
This result in turn yields a randomized $O^{*}(2^{3k/2})$ algorithm for
$(n-k)$-Coloring (also known as Dual Coloring), improving the previous
$O^{*}(4^{k})$ bound. We then introduce a smaller parameterization,
$(\omega+\overline{\mu}-k)$-Coloring, where $\omega$ is the clique number and
$\overline{\mu}$ is the size of a maximum matching in the complement graph;
since $\omega+\overline{\mu}\le n$ for any graph, this problem is strictly
harder. Using the same co-triangle-packing argument, we obtain a randomized
$O^{*}(2^{6k})$ algorithm, establishing its fixed-parameter tractability for a
smaller parameter. Complementing this finding, we show that no fixed-parameter
tractable algorithm exists for $(\omega-k)$-Coloring or
$(\overline{\mu}-k)$-Coloring under standard complexity assumptions.
The story of how diffusion models create—and what they leave behind I’m excited to share my new piece, How AI Generates: From Noise to Form. Diffusion models are behind much of today’s generative AI—image synthesis, text-to-art, even video. But how do they actually work? And what are their limits? My goal in this essay is […]
The story of how diffusion models create—and what they leave behind
I’m excited to share my new piece, How AI Generates: From Noise to Form.
Diffusion models are behind much of today’s generative AI—image synthesis, text-to-art, even video. But how do they actually work? And what are their limits?
My goal in this essay is to give readers a way in—to make the core ideas approachable while still keeping the essentials intact. Along the way, I walk through:
Why diffusion models corrupt data step by step, then learn to reverse the damage
How generation reduces to a series of prediction tasks
Why prompts guide but cannot fully constrain creations
And what glitches like the six-fingered hand reveal about the gap between surface and meaning
I start with a scene from the US Open to set the stage, but the heart of the piece is about how these models generate—and what they leave behind.
Authors: Partha Mukhopadhyay, C Ramya, Pratik Shastri
We design the first efficient polynomial identity testing algorithms over the
nonassociative polynomial algebra. In particular, multiplication among the
formal variables is commutative but it is not associative. This complements the
strong lower bound results obtained over this algebra by Hrube\v{s},
Yehudayoff, and Wigderson (2010) and Fijalkow, Lagarde, Ohlmann, and Serre
(2021) from the identity testing perspective. Our main results are the
following:
(1) We construct nonassociative algebras (both commutative and
noncommutative) which have no low degree identities. As a result, we obtain the
first Amitsur-Levitzki type theorems over nonassociative polynomial algebras.
As a direct consequence, we obtain randomized polynomial-time black-box PIT
algorithms for nonassociative polynomials which allow evaluation over such
algebras.
(2) On the derandomization side, we give a deterministic polynomial-time
identity testing algorithm for nonassociative polynomials given by arithmetic
circuits in the white-box setting. Previously, such an algorithm was known with
the additional restriction of noncommutativity.
(3) In the black-box setting, we construct a hitting set of
quasipolynomial-size for nonassociative polynomials computed by arithmetic
circuits of small depth. Understanding the black-box complexity of identity
testing, even in the randomized setting, was open prior to our work.
We design the first efficient polynomial identity testing algorithms over the
nonassociative polynomial algebra. In particular, multiplication among the
formal variables is commutative but it is not associative. This complements the
strong lower bound results obtained over this algebra by Hrube\v{s},
Yehudayoff, and Wigderson (2010) and Fijalkow, Lagarde, Ohlmann, and Serre
(2021) from the identity testing perspective. Our main results are the
following:
(1) We construct nonassociative algebras (both commutative and
noncommutative) which have no low degree identities. As a result, we obtain the
first Amitsur-Levitzki type theorems over nonassociative polynomial algebras.
As a direct consequence, we obtain randomized polynomial-time black-box PIT
algorithms for nonassociative polynomials which allow evaluation over such
algebras.
(2) On the derandomization side, we give a deterministic polynomial-time
identity testing algorithm for nonassociative polynomials given by arithmetic
circuits in the white-box setting. Previously, such an algorithm was known with
the additional restriction of noncommutativity.
(3) In the black-box setting, we construct a hitting set of
quasipolynomial-size for nonassociative polynomials computed by arithmetic
circuits of small depth. Understanding the black-box complexity of identity
testing, even in the randomized setting, was open prior to our work.
Arithmetic circuits are a natural well-studied model for computing
multivariate polynomials over a field. In this paper, we study planar
arithmetic circuits. These are circuits whose underlying graph is planar. In
particular, we prove an $\Omega(n\log n)$ lower bound on the size of planar
arithmetic circuits computing explicit bilinear forms on $2n$ variables. As a
consequence, we get an $\Omega(n\log n)$ lower bound on the size of arithmetic
formulas and planar algebraic branching programs computing explicit bilinear
forms on $2n$ variables. This is the first such lower bound on the formula
complexity of an explicit bilinear form. In the case of read-once planar
circuits, we show $\Omega(n^2)$ size lower bounds for computing explicit
bilinear forms on $2n$ variables. Furthermore, we prove fine separations
between the various planar models of computations mentioned above.
In addition to this, we look at multi-output planar circuits and show
$\Omega(n^{4/3})$ size lower bound for computing an explicit linear
transformation on $n$-variables. For a suitable definition of multi-output
formulas, we extend the above result to get an $\Omega(n^2/\log n)$ size lower
bound. As a consequence, we demonstrate that there exists an $n$-variate
polynomial computable by an $n^{1 + o(1)}$-sized formula such that any
multi-output planar circuit (resp., multi-output formula) simultaneously
computing all its first-order partial derivatives requires size
$\Omega(n^{4/3})$ (resp., $\Omega(n^2/\log n)$). This shows that a statement
analogous to that of Baur, Strassen (1983) does not hold in the case of planar
circuits and formulas.
Arithmetic circuits are a natural well-studied model for computing
multivariate polynomials over a field. In this paper, we study planar
arithmetic circuits. These are circuits whose underlying graph is planar. In
particular, we prove an $\Omega(n\log n)$ lower bound on the size of planar
arithmetic circuits computing explicit bilinear forms on $2n$ variables. As a
consequence, we get an $\Omega(n\log n)$ lower bound on the size of arithmetic
formulas and planar algebraic branching programs computing explicit bilinear
forms on $2n$ variables. This is the first such lower bound on the formula
complexity of an explicit bilinear form. In the case of read-once planar
circuits, we show $\Omega(n^2)$ size lower bounds for computing explicit
bilinear forms on $2n$ variables. Furthermore, we prove fine separations
between the various planar models of computations mentioned above.
In addition to this, we look at multi-output planar circuits and show
$\Omega(n^{4/3})$ size lower bound for computing an explicit linear
transformation on $n$-variables. For a suitable definition of multi-output
formulas, we extend the above result to get an $\Omega(n^2/\log n)$ size lower
bound. As a consequence, we demonstrate that there exists an $n$-variate
polynomial computable by an $n^{1 + o(1)}$-sized formula such that any
multi-output planar circuit (resp., multi-output formula) simultaneously
computing all its first-order partial derivatives requires size
$\Omega(n^{4/3})$ (resp., $\Omega(n^2/\log n)$). This shows that a statement
analogous to that of Baur, Strassen (1983) does not hold in the case of planar
circuits and formulas.
Authors: Alessandro Giovanni Alberti, Flavio Chierichetti, Mirko Giacchini, Daniele Muscillo, Alessandro Panconesi, Erasmo Tani
The New York Times (NYT) games have found widespread popularity in recent
years and reportedly account for an increasing fraction of the newspaper's
readership. In this paper, we bring the computational lens to the study of New
York Times games and consider four of them not previously studied: Letter
Boxed, Pips, Strands and Tiles. We show that these games can be just as hard as
they are fun. In particular, we characterize the hardness of several variants
of computational problems related to these popular puzzle games. For Letter
Boxed, we show that deciding whether an instance is solvable is in general
NP-Complete, while in some parameter settings it can be done in polynomial
time. Similarly, for Pips we prove that deciding whether a puzzle has a
solution is NP-Complete even in some restricted classes of instances. We then
show that one natural computational problem arising from Strands is NP-Complete
in most parameter settings. Finally, we demonstrate that deciding whether a
Tiles puzzle is solvable with a single, uninterrupted combo requires polynomial
time.
The New York Times (NYT) games have found widespread popularity in recent
years and reportedly account for an increasing fraction of the newspaper's
readership. In this paper, we bring the computational lens to the study of New
York Times games and consider four of them not previously studied: Letter
Boxed, Pips, Strands and Tiles. We show that these games can be just as hard as
they are fun. In particular, we characterize the hardness of several variants
of computational problems related to these popular puzzle games. For Letter
Boxed, we show that deciding whether an instance is solvable is in general
NP-Complete, while in some parameter settings it can be done in polynomial
time. Similarly, for Pips we prove that deciding whether a puzzle has a
solution is NP-Complete even in some restricted classes of instances. We then
show that one natural computational problem arising from Strands is NP-Complete
in most parameter settings. Finally, we demonstrate that deciding whether a
Tiles puzzle is solvable with a single, uninterrupted combo requires polynomial
time.
We investigate the closure properties of read-once oblivious Algebraic
Branching Programs (roABPs) under various natural algebraic operations and
prove the following.
- Non-closure under factoring: There is a sequence of explicit polynomials
$(f_n(x_1,\ldots, x_n))_n$ that have $\mathsf{poly}(n)$-sized roABPs such that
some irreducible factor of $f_n$ does not have roABPs of superpolynomial size
in any order.
- Non-closure under powering: There is a sequence of polynomials
$(f_n(x_1,\ldots, x_n))_n$ with $\mathsf{poly}(n)$-sized roABPs such that any
super-constant power of $f_n$ does not have roABPs of polynomial size in any
order (and $f_n^n$ requires exponential size in any order).
- Non-closure under symmetric compositions: There are symmetric polynomials
$(f_n(e_1,\ldots, e_n))_n$ that have roABPs of polynomial size such that
$f_n(x_1,\ldots, x_n)$ do not have roABPs of subexponential size. (Here,
$e_1,\ldots, e_n$ denote the elementary symmetric polynomials in $n$
variables.)
These results should be viewed in light of known results on models such as
algebraic circuits, (general) algebraic branching programs, formulas and
constant-depth circuits, all of which are known to be closed under these
operations.
To prove non-closure under factoring, we construct hard polynomials based on
expander graphs using gadgets that lift their hardness from sparse polynomials
to roABPs. For symmetric compositions, we show that the circulant polynomial
requires roABPs of exponential size in every variable order.
We investigate the closure properties of read-once oblivious Algebraic
Branching Programs (roABPs) under various natural algebraic operations and
prove the following.
- Non-closure under factoring: There is a sequence of explicit polynomials
$(f_n(x_1,\ldots, x_n))_n$ that have $\mathsf{poly}(n)$-sized roABPs such that
some irreducible factor of $f_n$ does not have roABPs of superpolynomial size
in any order.
- Non-closure under powering: There is a sequence of polynomials
$(f_n(x_1,\ldots, x_n))_n$ with $\mathsf{poly}(n)$-sized roABPs such that any
super-constant power of $f_n$ does not have roABPs of polynomial size in any
order (and $f_n^n$ requires exponential size in any order).
- Non-closure under symmetric compositions: There are symmetric polynomials
$(f_n(e_1,\ldots, e_n))_n$ that have roABPs of polynomial size such that
$f_n(x_1,\ldots, x_n)$ do not have roABPs of subexponential size. (Here,
$e_1,\ldots, e_n$ denote the elementary symmetric polynomials in $n$
variables.)
These results should be viewed in light of known results on models such as
algebraic circuits, (general) algebraic branching programs, formulas and
constant-depth circuits, all of which are known to be closed under these
operations.
To prove non-closure under factoring, we construct hard polynomials based on
expander graphs using gadgets that lift their hardness from sparse polynomials
to roABPs. For symmetric compositions, we show that the circulant polynomial
requires roABPs of exponential size in every variable order.
We show a dichotomy result for $p$-pass streaming algorithms for all CSPs and
for up to polynomially many passes. More precisely, we prove that for any arity
parameter $k$, finite alphabet $\Sigma$, collection $\mathcal{F}$ of $k$-ary
predicates over $\Sigma$ and any $c\in (0,1)$, there exists $00$ there is a constant pass, $O_{\varepsilon}(\log
n)$-space randomized streaming algorithm solving the promise problem
$\text{MaxCSP}(\mathcal{F})[c,s-\varepsilon]$. That is, the algorithm accepts
inputs with value at least $c$ with probability at least $2/3$, and rejects
inputs with value at most $s-\varepsilon$ with probability at least $2/3$.
2. For all $\varepsilon>0$, any $p$-pass (even randomized) streaming
algorithm that solves the promise problem
$\text{MaxCSP}(\mathcal{F})[c,s+\varepsilon]$ must use
$\Omega_{\varepsilon}(n^{1/3}/p)$ space.
Our approximation algorithm is based on a certain linear-programming
relaxation of the CSP and on a distributed algorithm that approximates its
value. This part builds on the works [Yoshida, STOC 2011] and [Saxena, Singer,
Sudan, Velusamy, SODA 2025]. For our hardness result we show how to translate
an integrality gap of the linear program into a family of hard instances, which
we then analyze via studying a related communication complexity problem. That
analysis is based on discrete Fourier analysis and builds on a prior work of
the authors and on the work [Chou, Golovnev, Sudan, Velingker, Velusamy, J.ACM
2024].
We show a dichotomy result for $p$-pass streaming algorithms for all CSPs and
for up to polynomially many passes. More precisely, we prove that for any arity
parameter $k$, finite alphabet $\Sigma$, collection $\mathcal{F}$ of $k$-ary
predicates over $\Sigma$ and any $c\in (0,1)$, there exists $00$ there is a constant pass, $O_{\varepsilon}(\log
n)$-space randomized streaming algorithm solving the promise problem
$\text{MaxCSP}(\mathcal{F})[c,s-\varepsilon]$. That is, the algorithm accepts
inputs with value at least $c$ with probability at least $2/3$, and rejects
inputs with value at most $s-\varepsilon$ with probability at least $2/3$.
2. For all $\varepsilon>0$, any $p$-pass (even randomized) streaming
algorithm that solves the promise problem
$\text{MaxCSP}(\mathcal{F})[c,s+\varepsilon]$ must use
$\Omega_{\varepsilon}(n^{1/3}/p)$ space.
Our approximation algorithm is based on a certain linear-programming
relaxation of the CSP and on a distributed algorithm that approximates its
value. This part builds on the works [Yoshida, STOC 2011] and [Saxena, Singer,
Sudan, Velusamy, SODA 2025]. For our hardness result we show how to translate
an integrality gap of the linear program into a family of hard instances, which
we then analyze via studying a related communication complexity problem. That
analysis is based on discrete Fourier analysis and builds on a prior work of
the authors and on the work [Chou, Golovnev, Sudan, Velingker, Velusamy, J.ACM
2024].
Approximate Nearest Neighbor Search (ANNS) plays a critical role in
applications such as search engines, recommender systems, and RAG for LLMs.
Vector quantization (VQ), a crucial technique for ANNS, is commonly used to
reduce space overhead and accelerate distance computations. However, despite
significant research advances, state-of-the-art VQ methods still face
challenges in balancing encoding efficiency and quantization accuracy. To
address these limitations, we propose a novel VQ method called SAQ. To improve
accuracy, SAQ employs a new dimension segmentation technique to strategically
partition PCA-projected vectors into segments along their dimensions. By
prioritizing leading dimension segments with larger magnitudes, SAQ allocates
more bits to high-impact segments, optimizing the use of the available space
quota. An efficient dynamic programming algorithm is developed to optimize
dimension segmentation and bit allocation, ensuring minimal quantization error.
To speed up vector encoding, SAQ devises a code adjustment technique to first
quantize each dimension independently and then progressively refine quantized
vectors using a coordinate-descent-like approach to avoid exhaustive
enumeration. Extensive experiments demonstrate SAQ's superiority over classical
methods (e.g., PQ, PCA) and recent state-of-the-art approaches (e.g., LVQ,
Extended RabitQ). SAQ achieves up to 80% reduction in quantization error and
accelerates encoding speed by over 80x compared to Extended RabitQ.
Approximate Nearest Neighbor Search (ANNS) plays a critical role in
applications such as search engines, recommender systems, and RAG for LLMs.
Vector quantization (VQ), a crucial technique for ANNS, is commonly used to
reduce space overhead and accelerate distance computations. However, despite
significant research advances, state-of-the-art VQ methods still face
challenges in balancing encoding efficiency and quantization accuracy. To
address these limitations, we propose a novel VQ method called SAQ. To improve
accuracy, SAQ employs a new dimension segmentation technique to strategically
partition PCA-projected vectors into segments along their dimensions. By
prioritizing leading dimension segments with larger magnitudes, SAQ allocates
more bits to high-impact segments, optimizing the use of the available space
quota. An efficient dynamic programming algorithm is developed to optimize
dimension segmentation and bit allocation, ensuring minimal quantization error.
To speed up vector encoding, SAQ devises a code adjustment technique to first
quantize each dimension independently and then progressively refine quantized
vectors using a coordinate-descent-like approach to avoid exhaustive
enumeration. Extensive experiments demonstrate SAQ's superiority over classical
methods (e.g., PQ, PCA) and recent state-of-the-art approaches (e.g., LVQ,
Extended RabitQ). SAQ achieves up to 80% reduction in quantization error and
accelerates encoding speed by over 80x compared to Extended RabitQ.
Decision trees are a ubiquitous model for classification and regression tasks
due to their interpretability and efficiency. However, solving the optimal
decision tree (ODT) problem remains a challenging combinatorial optimization
task. Even for the simplest splitting rules--axis-parallel hyperplanes--it is
NP-hard to optimize. In Part I of this series, we rigorously defined the proper
decision tree model through four axioms and, based on these, introduced four
formal definitions of the ODT problem. From these definitions, we derived four
generic algorithms capable of solving ODT problems for arbitrary decision trees
satisfying the axioms. We also analyzed the combinatorial geometric properties
of hypersurfaces, showing that decision trees defined by polynomial
hypersurface splitting rules satisfy the proper axioms that we proposed.
In this second paper (Part II) of this two-part series, building on the
algorithmic and geometric foundations established in Part I, we introduce the
first hypersurface decision tree (HODT) algorithm. To the best of our
knowledge, existing optimal decision tree methods are, to date, limited to
hyperplane splitting rules--a special case of hypersurfaces--and rely on
general-purpose solvers. In contrast, our HODT algorithm addresses the general
hypersurface decision tree model without requiring external solvers.
Using synthetic datasets generated from ground-truth hyperplane decision
trees, we vary tree size, data size, dimensionality, and label and feature
noise. Results showing that our algorithm recovers the ground truth more
accurately than axis-parallel trees and exhibits greater robustness to noise.
We also analyzed generalization performance across 30 real-world datasets,
showing that HODT can achieve up to 30% higher accuracy than the
state-of-the-art optimal axis-parallel decision tree algorithm when tree
complexity is properly controlled.
Decision trees are a ubiquitous model for classification and regression tasks
due to their interpretability and efficiency. However, solving the optimal
decision tree (ODT) problem remains a challenging combinatorial optimization
task. Even for the simplest splitting rules--axis-parallel hyperplanes--it is
NP-hard to optimize. In Part I of this series, we rigorously defined the proper
decision tree model through four axioms and, based on these, introduced four
formal definitions of the ODT problem. From these definitions, we derived four
generic algorithms capable of solving ODT problems for arbitrary decision trees
satisfying the axioms. We also analyzed the combinatorial geometric properties
of hypersurfaces, showing that decision trees defined by polynomial
hypersurface splitting rules satisfy the proper axioms that we proposed.
In this second paper (Part II) of this two-part series, building on the
algorithmic and geometric foundations established in Part I, we introduce the
first hypersurface decision tree (HODT) algorithm. To the best of our
knowledge, existing optimal decision tree methods are, to date, limited to
hyperplane splitting rules--a special case of hypersurfaces--and rely on
general-purpose solvers. In contrast, our HODT algorithm addresses the general
hypersurface decision tree model without requiring external solvers.
Using synthetic datasets generated from ground-truth hyperplane decision
trees, we vary tree size, data size, dimensionality, and label and feature
noise. Results showing that our algorithm recovers the ground truth more
accurately than axis-parallel trees and exhibits greater robustness to noise.
We also analyzed generalization performance across 30 real-world datasets,
showing that HODT can achieve up to 30% higher accuracy than the
state-of-the-art optimal axis-parallel decision tree algorithm when tree
complexity is properly controlled.
Authors: Bart M. P. Jansen, Jeroen S. K. Lamme, Ruben F. A. Verhaegh
We study the parameterized complexity of a recently introduced multi-agent
variant of the Kidney Exchange problem. Given a directed graph $G$ and integers
$d$ and $k$, the standard problem asks whether $G$ contains a packing of
vertex-disjoint cycles, each of length $\leq d$, covering at least $k$ vertices
in total. In the multi-agent setting we consider, the vertex set is partitioned
over several agents who reject a cycle packing as solution if it can be
modified into an alternative packing that covers more of their own vertices. A
cycle packing is called rejection-proof if no agent rejects it and the problem
asks whether such a packing exists that covers at least $k$ vertices.
We exploit the sunflower lemma on a set packing formulation of the problem to
give a kernel for this $\Sigma_2^P$-complete problem that is polynomial in $k$
for all constant values of $d$. We also provide a $2^{\mathcal{O}(k \log k)} +
n^{\mathcal{O}(1)}$ algorithm based on it and show that this FPT algorithm is
asymptotically optimal under the ETH. Further, we generalize the problem by
including an additional positive integer $c$ in the input that naturally
captures how much agents can modify a given cycle packing to reject it. For
every constant $c$, the resulting problem simplifies from being
$\Sigma_2^P$-complete to NP-complete. With a single-exponential algorithm for
the setting where $c = 1$, we show this to be strictly easier under the ETH
than when $c = 2$. In turn, we show that any $c \geq 2$ yields a problem that
is essentially as hard as the original problem with $c$ unbounded. This
displays an interesting discrepancy between the classical and parameterized
complexity of the problem and gives a good view of what makes it hard.
We study the parameterized complexity of a recently introduced multi-agent
variant of the Kidney Exchange problem. Given a directed graph $G$ and integers
$d$ and $k$, the standard problem asks whether $G$ contains a packing of
vertex-disjoint cycles, each of length $\leq d$, covering at least $k$ vertices
in total. In the multi-agent setting we consider, the vertex set is partitioned
over several agents who reject a cycle packing as solution if it can be
modified into an alternative packing that covers more of their own vertices. A
cycle packing is called rejection-proof if no agent rejects it and the problem
asks whether such a packing exists that covers at least $k$ vertices.
We exploit the sunflower lemma on a set packing formulation of the problem to
give a kernel for this $\Sigma_2^P$-complete problem that is polynomial in $k$
for all constant values of $d$. We also provide a $2^{\mathcal{O}(k \log k)} +
n^{\mathcal{O}(1)}$ algorithm based on it and show that this FPT algorithm is
asymptotically optimal under the ETH. Further, we generalize the problem by
including an additional positive integer $c$ in the input that naturally
captures how much agents can modify a given cycle packing to reject it. For
every constant $c$, the resulting problem simplifies from being
$\Sigma_2^P$-complete to NP-complete. With a single-exponential algorithm for
the setting where $c = 1$, we show this to be strictly easier under the ETH
than when $c = 2$. In turn, we show that any $c \geq 2$ yields a problem that
is essentially as hard as the original problem with $c$ unbounded. This
displays an interesting discrepancy between the classical and parameterized
complexity of the problem and gives a good view of what makes it hard.
Let $G=(V, E)$ be a simple undirected graph. A closed neighbourhood of an
edge $e=uv$ between two vertices $u$ and $v$ of $G$, denoted by $N_G[e]$, is
the set of vertices in the neighbourhood of $u$ and $v$ including $\{u,v\}$. A
subset $L$ of $V$ is said to be liar's vertex-edge dominating set if $(i)$ for
every edge $e\in E$, $|N_G[e]\cap L|\geq 2$ and $(ii)$ for every pair of
distinct edges $e,e'$, $|(N_G[e]\cup N_G[e'])\cap L|\geq 3$. The minimum liar's
vertex-edge domination problem is to find the liar's vertex-edge dominating set
of minimum cardinality. In this article, we show that the liar's vertex-edge
domination problem is NP-complete in unit disk graphs, and we design a
polynomial time approximation scheme(PTAS) for the minimum liar's vertex-edge
domination problem in unit disk graphs.
Let $G=(V, E)$ be a simple undirected graph. A closed neighbourhood of an
edge $e=uv$ between two vertices $u$ and $v$ of $G$, denoted by $N_G[e]$, is
the set of vertices in the neighbourhood of $u$ and $v$ including $\{u,v\}$. A
subset $L$ of $V$ is said to be liar's vertex-edge dominating set if $(i)$ for
every edge $e\in E$, $|N_G[e]\cap L|\geq 2$ and $(ii)$ for every pair of
distinct edges $e,e'$, $|(N_G[e]\cup N_G[e'])\cap L|\geq 3$. The minimum liar's
vertex-edge domination problem is to find the liar's vertex-edge dominating set
of minimum cardinality. In this article, we show that the liar's vertex-edge
domination problem is NP-complete in unit disk graphs, and we design a
polynomial time approximation scheme(PTAS) for the minimum liar's vertex-edge
domination problem in unit disk graphs.
Authors: Soichiro Migita, Kyotaro Uehata, Tomohiro I
A Straight-Line Program (SLP) for a stirng $T$ is a context-free grammar in
Chomsky normal form that derives $T$ only, which can be seen as a compressed
form of $T$. Kida et al.\ introduced collage systems [Theor. Comput. Sci.,
2003] to generalize SLPs by adding repetition rules and truncation rules. The
smallest size $c(T)$ of collage systems for $T$ has gained attention to see how
these generalized rules improve the compression ability of SLPs. Navarro et al.
[IEEE Trans. Inf. Theory, 2021] showed that $c(T) \in O(z(T))$ and there is a
string family with $c(T) \in \Omega(b(T) \log |T|)$, where $z(T)$ is the number
of Lempel-Ziv parsing of $T$ and $b(T)$ is the smallest size of bidirectional
schemes for $T$. They also introduced a subclass of collage systems, called
internal collage systems, and proved that its smallest size $\hat{c}(T)$ for
$T$ is at least $b(T)$. While $c(T) \le \hat{c}(T)$ is obvious, it is unknown
how large $\hat{c}(T)$ is compared to $c(T)$. In this paper, we prove that
$\hat{c}(T) = \Theta(c(T))$ by showing that any collage system of size $m$ can
be transformed into an internal collage system of size $O(m)$ in $O(m^2)$ time.
Thanks to this result, we can focus on internal collage systems to study the
asymptotic behavior of $c(T)$, which helps to suppress excess use of truncation
rules. As a direct application, we get $b(T) = O(c(T))$, which answers an open
question posed in [Navarro et al., IEEE Trans. Inf. Theory, 2021]. We also give
a MAX-SAT formulation to compute $\hat{c}(T)$ for a given $T$.
A Straight-Line Program (SLP) for a stirng $T$ is a context-free grammar in
Chomsky normal form that derives $T$ only, which can be seen as a compressed
form of $T$. Kida et al.\ introduced collage systems [Theor. Comput. Sci.,
2003] to generalize SLPs by adding repetition rules and truncation rules. The
smallest size $c(T)$ of collage systems for $T$ has gained attention to see how
these generalized rules improve the compression ability of SLPs. Navarro et al.
[IEEE Trans. Inf. Theory, 2021] showed that $c(T) \in O(z(T))$ and there is a
string family with $c(T) \in \Omega(b(T) \log |T|)$, where $z(T)$ is the number
of Lempel-Ziv parsing of $T$ and $b(T)$ is the smallest size of bidirectional
schemes for $T$. They also introduced a subclass of collage systems, called
internal collage systems, and proved that its smallest size $\hat{c}(T)$ for
$T$ is at least $b(T)$. While $c(T) \le \hat{c}(T)$ is obvious, it is unknown
how large $\hat{c}(T)$ is compared to $c(T)$. In this paper, we prove that
$\hat{c}(T) = \Theta(c(T))$ by showing that any collage system of size $m$ can
be transformed into an internal collage system of size $O(m)$ in $O(m^2)$ time.
Thanks to this result, we can focus on internal collage systems to study the
asymptotic behavior of $c(T)$, which helps to suppress excess use of truncation
rules. As a direct application, we get $b(T) = O(c(T))$, which answers an open
question posed in [Navarro et al., IEEE Trans. Inf. Theory, 2021]. We also give
a MAX-SAT formulation to compute $\hat{c}(T)$ for a given $T$.
In this work we present PercIS, an algorithm based on Importance Sampling to
approximate the percolation centrality of all the nodes of a graph. Percolation
centrality is a generalization of betweenness centrality to attributed graphs,
and is a useful measure to quantify the importance of the vertices in a
contagious process or to diffuse information. However, it is impractical to
compute it exactly on modern-sized networks.
First, we highlight key limitations of state-of-the-art sampling-based
approximation methods for the percolation centrality, showing that in most
cases they cannot achieve accurate solutions efficiently. Then, we propose and
analyze a novel sampling algorithm based on Importance Sampling, proving tight
sample size bounds to achieve high-quality approximations.
Our extensive experimental evaluation shows that PercIS computes high-quality
estimates and scales to large real-world networks, while significantly
outperforming, in terms of sample sizes, accuracy and running times, the
state-of-the-art.
In this work we present PercIS, an algorithm based on Importance Sampling to
approximate the percolation centrality of all the nodes of a graph. Percolation
centrality is a generalization of betweenness centrality to attributed graphs,
and is a useful measure to quantify the importance of the vertices in a
contagious process or to diffuse information. However, it is impractical to
compute it exactly on modern-sized networks.
First, we highlight key limitations of state-of-the-art sampling-based
approximation methods for the percolation centrality, showing that in most
cases they cannot achieve accurate solutions efficiently. Then, we propose and
analyze a novel sampling algorithm based on Importance Sampling, proving tight
sample size bounds to achieve high-quality approximations.
Our extensive experimental evaluation shows that PercIS computes high-quality
estimates and scales to large real-world networks, while significantly
outperforming, in terms of sample sizes, accuracy and running times, the
state-of-the-art.
Authors: Amirali Madani, Anil Maheshwari, Babak Miraftab, Paweł Żyliński
The widely studied edge modification problems ask how to minimally alter a
graph to satisfy certain structural properties. In this paper, we introduce and
study a new edge modification problem centered around transforming a given
graph into a triangle-covered graph (one in which every vertex belongs to at
least one triangle). We first present tight lower bounds on the number of edges
in any connected triangle-covered graph of order $n$, and then we characterize
all connected graphs that attain this minimum edge count. For a graph $G$, we
define the notion of a $\Delta$-completion set as a set of non-edges of $G$
whose addition to $G$ results in a triangle-covered graph. We prove that the
decision problem of finding a $\Delta$-completion set of size at most $t\geq0$
is $\mathbb{NP}$-complete and does not admit a constant-factor approximation
algorithm under standard complexity assumptions. Moreover, we show that this
problem remains $\mathbb{NP}$-complete even when the input is restricted to
connected bipartite graphs. We then study the problem from an algorithmic
perspective, providing tight bounds on the minimum $\Delta$-completion set size
for several graph classes, including trees, chordal graphs, and cactus graphs.
Furthermore, we show that the triangle-covered problem admits an $(\ln n
+1)$-approximation algorithm for general graphs. For trees and chordal graphs,
we design algorithms that compute minimum $\Delta$-completion sets. Finally, we
show that the threshold for a random graph $\mathbb{G}(n, p)$ to be
triangle-covered occurs at $n^{-2/3}$.
The widely studied edge modification problems ask how to minimally alter a
graph to satisfy certain structural properties. In this paper, we introduce and
study a new edge modification problem centered around transforming a given
graph into a triangle-covered graph (one in which every vertex belongs to at
least one triangle). We first present tight lower bounds on the number of edges
in any connected triangle-covered graph of order $n$, and then we characterize
all connected graphs that attain this minimum edge count. For a graph $G$, we
define the notion of a $\Delta$-completion set as a set of non-edges of $G$
whose addition to $G$ results in a triangle-covered graph. We prove that the
decision problem of finding a $\Delta$-completion set of size at most $t\geq0$
is $\mathbb{NP}$-complete and does not admit a constant-factor approximation
algorithm under standard complexity assumptions. Moreover, we show that this
problem remains $\mathbb{NP}$-complete even when the input is restricted to
connected bipartite graphs. We then study the problem from an algorithmic
perspective, providing tight bounds on the minimum $\Delta$-completion set size
for several graph classes, including trees, chordal graphs, and cactus graphs.
Furthermore, we show that the triangle-covered problem admits an $(\ln n
+1)$-approximation algorithm for general graphs. For trees and chordal graphs,
we design algorithms that compute minimum $\Delta$-completion sets. Finally, we
show that the threshold for a random graph $\mathbb{G}(n, p)$ to be
triangle-covered occurs at $n^{-2/3}$.
Authors: Hins Hu, Rhea Goswami, Hongyi Jiang, Samitha Samaranayake
Micro-transit services offer a promising solution to enhance urban mobility
and access, particularly by complementing existing public transit. However,
effectively designing these services requires determining optimal service zones
for these on-demand shuttles, a complex challenge often constrained by
operating budgets and transit agency priorities. This paper presents a novel
two-phase algorithmic framework for designing optimal micro-transit service
zones based on the objective of maximizing served demand. A key innovation is
our adaptation of the shareability graph concept from its traditional use in
dynamic trip assignment to the distinct challenge of static spatial zoning. We
redefine shareability by considering geographical proximity within a specified
diameter constraint, rather than trip characteristics. In Phase 1, the
framework employs a highly scalable algorithm to generate a comprehensive set
of candidate zones. In Phase 2, it formulates the selection of a specified
number of zones as a Weighted Maximum Coverage Problem, which can be
efficiently solved by an integer programming solver. Evaluations on real-world
data from Chattanooga, TN, and synthetic datasets show that our framework
outperforms a baseline algorithm, serving 27.03% more demand in practice and up
to 49.5% more demand in synthetic settings.
Micro-transit services offer a promising solution to enhance urban mobility
and access, particularly by complementing existing public transit. However,
effectively designing these services requires determining optimal service zones
for these on-demand shuttles, a complex challenge often constrained by
operating budgets and transit agency priorities. This paper presents a novel
two-phase algorithmic framework for designing optimal micro-transit service
zones based on the objective of maximizing served demand. A key innovation is
our adaptation of the shareability graph concept from its traditional use in
dynamic trip assignment to the distinct challenge of static spatial zoning. We
redefine shareability by considering geographical proximity within a specified
diameter constraint, rather than trip characteristics. In Phase 1, the
framework employs a highly scalable algorithm to generate a comprehensive set
of candidate zones. In Phase 2, it formulates the selection of a specified
number of zones as a Weighted Maximum Coverage Problem, which can be
efficiently solved by an integer programming solver. Evaluations on real-world
data from Chattanooga, TN, and synthetic datasets show that our framework
outperforms a baseline algorithm, serving 27.03% more demand in practice and up
to 49.5% more demand in synthetic settings.
The Horton-Strahler number (HS) is a measure of branching complexity of
rooted trees, introduced in hydrology and later studied in parallel computing
under the name register function. While its order of growth is well understood
for classical random trees, fluctuation behavior has largely resisted analysis.
In this work we investigate the HS in the setting of butterfly trees -- binary
trees constructed from butterfly permutations, a rich class of separable
permutations with origins in numerical linear algebra and parallel
architectures. For the subclass of simple butterfly trees, we exploit their
recursive gluing structure to model the HS as an additive functional of a
finite-state Markov process. This framework yields sharp distributional
results, including a law of large numbers and a Central Limit Theorem with
explicit variance growth, providing what appears to be the first genuine
Gaussian limit law for the HS in a nontrivial random tree model. Extending to
biased constructions, we further establish functional limit theorems via
analytic and probabilistic tools. For general butterfly trees, while exact
analysis remains open, empirical sampling shows that the HS distribution is
confined to a narrower support than in classical models, and appears to
concentrate tightly near the upper bound $\lfloor \log_4 N\rfloor$.
The Horton-Strahler number (HS) is a measure of branching complexity of
rooted trees, introduced in hydrology and later studied in parallel computing
under the name register function. While its order of growth is well understood
for classical random trees, fluctuation behavior has largely resisted analysis.
In this work we investigate the HS in the setting of butterfly trees -- binary
trees constructed from butterfly permutations, a rich class of separable
permutations with origins in numerical linear algebra and parallel
architectures. For the subclass of simple butterfly trees, we exploit their
recursive gluing structure to model the HS as an additive functional of a
finite-state Markov process. This framework yields sharp distributional
results, including a law of large numbers and a Central Limit Theorem with
explicit variance growth, providing what appears to be the first genuine
Gaussian limit law for the HS in a nontrivial random tree model. Extending to
biased constructions, we further establish functional limit theorems via
analytic and probabilistic tools. For general butterfly trees, while exact
analysis remains open, empirical sampling shows that the HS distribution is
confined to a narrower support than in classical models, and appears to
concentrate tightly near the upper bound $\lfloor \log_4 N\rfloor$.
The Marcus-Spielman-Srivastava theorem (Annals of Mathematics, 2015) for the
Kadison-Singer conjecture implies the following result in spectral graph
theory: For any undirected graph $G = (V,E)$ with a maximum edge effective
resistance at most $\alpha$, there exists a partition of its edge set $E$ into
$E_1 \cup E_2$ such that the two edge-induced subgraphs of $G$ spectrally
approximates $(1/2)G$ with a relative error $O(\sqrt{\alpha})$. However, the
proof of this theorem is non-constructive. It remains an open question whether
such a partition can be found in polynomial time, even for special classes of
graphs.
In this paper, we explore polynomial-time algorithms for partitioning
circulant graphs via partitioning their generators. We develop an efficient
algorithm that partitions a circulant graph whose generators form an arithmetic
progression, with an error matching that in the Marcus-Spielman-Srivastava
theorem and optimal, up to a constant. On the other hand, we prove that if the
generators of a circulant graph are ``far" from an arithmetic progression, no
partition of the generators can yield two circulant subgraphs with an error
matching that in the Marcus-Spielman-Srivastava theorem.
In addition, we extend our algorithm to Cayley graphs whose generators are
from a product of multiple arithmetic progressions.
The Marcus-Spielman-Srivastava theorem (Annals of Mathematics, 2015) for the
Kadison-Singer conjecture implies the following result in spectral graph
theory: For any undirected graph $G = (V,E)$ with a maximum edge effective
resistance at most $\alpha$, there exists a partition of its edge set $E$ into
$E_1 \cup E_2$ such that the two edge-induced subgraphs of $G$ spectrally
approximates $(1/2)G$ with a relative error $O(\sqrt{\alpha})$. However, the
proof of this theorem is non-constructive. It remains an open question whether
such a partition can be found in polynomial time, even for special classes of
graphs.
In this paper, we explore polynomial-time algorithms for partitioning
circulant graphs via partitioning their generators. We develop an efficient
algorithm that partitions a circulant graph whose generators form an arithmetic
progression, with an error matching that in the Marcus-Spielman-Srivastava
theorem and optimal, up to a constant. On the other hand, we prove that if the
generators of a circulant graph are ``far" from an arithmetic progression, no
partition of the generators can yield two circulant subgraphs with an error
matching that in the Marcus-Spielman-Srivastava theorem.
In addition, we extend our algorithm to Cayley graphs whose generators are
from a product of multiple arithmetic progressions.
In the first paper (part I) of this series of two, we introduce four novel
definitions of the ODT problems: three for size-constrained trees and one for
depth-constrained trees. These definitions are stated unambiguously through
executable recursive programs, satisfying all criteria we propose for a formal
specification. In this sense, they resemble the "standard form" used in the
study of general-purpose solvers.
Grounded in algebraic programming theory-a relational formalism for deriving
correct-by-construction algorithms from specifications-we can not only
establish the existence or nonexistence of dynamic programming solutions but
also derive them constructively whenever they exist. Consequently, the four
generic problem definitions yield four novel optimal algorithms for ODT
problems with arbitrary splitting rules that satisfy the axioms and objective
functions of a given form. These algorithms encompass the known
depth-constrained, axis-parallel ODT algorithm as the special case, while
providing a unified, efficient, and elegant solution for the general ODT
problem.
In Part II, we present the first optimal hypersurface decision tree algorithm
and provide comprehensive experiments against axis-parallel decision tree
algorithms, including heuristic CART and state-of-the-art optimal methods. The
results demonstrate the significant potential of decision trees with flexible
splitting rules. Moreover, our framework is readily extendable to support
algorithms for constructing even more flexible decision trees, including those
with mixed splitting rules.
In the first paper (part I) of this series of two, we introduce four novel
definitions of the ODT problems: three for size-constrained trees and one for
depth-constrained trees. These definitions are stated unambiguously through
executable recursive programs, satisfying all criteria we propose for a formal
specification. In this sense, they resemble the "standard form" used in the
study of general-purpose solvers.
Grounded in algebraic programming theory-a relational formalism for deriving
correct-by-construction algorithms from specifications-we can not only
establish the existence or nonexistence of dynamic programming solutions but
also derive them constructively whenever they exist. Consequently, the four
generic problem definitions yield four novel optimal algorithms for ODT
problems with arbitrary splitting rules that satisfy the axioms and objective
functions of a given form. These algorithms encompass the known
depth-constrained, axis-parallel ODT algorithm as the special case, while
providing a unified, efficient, and elegant solution for the general ODT
problem.
In Part II, we present the first optimal hypersurface decision tree algorithm
and provide comprehensive experiments against axis-parallel decision tree
algorithms, including heuristic CART and state-of-the-art optimal methods. The
results demonstrate the significant potential of decision trees with flexible
splitting rules. Moreover, our framework is readily extendable to support
algorithms for constructing even more flexible decision trees, including those
with mixed splitting rules.
This paper presents the Chonkers algorithm, a novel content-defined chunking
method providing simultaneous strict guarantees on chunk size and edit
locality. Unlike existing algorithms such as Rabin fingerprinting and
anchor-based methods, Chonkers achieves bounded propagation of edits and
precise control over chunk sizes. I describe the algorithm's layered structure,
theoretical guarantees, implementation considerations, and introduce the Yarn
datatype, a deduplicated, merge-tree-based string representation benefiting
from Chonkers' strict guarantees.
This paper presents the Chonkers algorithm, a novel content-defined chunking
method providing simultaneous strict guarantees on chunk size and edit
locality. Unlike existing algorithms such as Rabin fingerprinting and
anchor-based methods, Chonkers achieves bounded propagation of edits and
precise control over chunk sizes. I describe the algorithm's layered structure,
theoretical guarantees, implementation considerations, and introduce the Yarn
datatype, a deduplicated, merge-tree-based string representation benefiting
from Chonkers' strict guarantees.
New Good Article on Wikipedia: Pythagorean addition(\(\mathbb{M}\)). This is the operation of computing the hypotenuse of a right triangle from its two sides. Because this is commutative and associative, it defines a commutative monoid, and Knuth defined it as a built-in binary operation in metafont, writing that it could likely replace most uses of square roots in software.
Back when people used slide rules instead of computers, some slide rules had special scales (positioning numbers by their square roots rather than their logs) that would allow them to perform this calculation, for instance in converting from Cartesian to polar coordinates: see “Find absolute value” on p.3 of this slide-rule instruction guide.
Nowadays most programming language libraries provide this operation as hypot.
Problematic new licensing requirements from Springer journals: you are forbidden from including any post-submission improvements in your openly-licensed preprints, must add a disclaimer to the preprints saying they are unimproved, are forbidden from creating any later version that makes changes to the format or content of the Springer-published version, and are not given any opportunity to object to or modify the terms of the license.
Right kite reptile tessellations, Dani Laura. The right kite with side ratio \(\sqrt2\) lets the tiles fit together particularly nicely, with some larger sides bisected by smaller sides of tiles.
Fraudulent publishing in the mathematical sciences(\(\mathbb{M}\),via): part I of a report of a joint committee of IMU and ICIAM consisting of Ilka Agricola, Lynn Heller, Wil Schilders, Moritz Schubotz, Peter Taylor, and Luis Vega. Part I is “where are we now” and part II (to come) is “what can we do”. I saw Agricola speak on this sort of thing a year ago and she tells a compelling story about how fraudulent publishing practices (by both publishers and authors) are damaging mathematics.
The recent unpleasantness over Poland is already causing me minor repercussions here in California (\(\mathbb{M}\)): my coauthor doesn’t want to risk flying to Warsaw, a potential repeat of this happening, and getting stranded there. So he has canceled his travel to ESA / ALGO to present our joint paper on bandwidth and BFS. Instead it will be presented as a prerecorded video.
I guess Europeans traveling to ALGO can always count on taking a train instead, a little more reliably than air travel to Warsaw after recent events, so I hope a dent in intercontinental attendees doesn’t hurt the conference too much. Anyway, best wishes to all in attendance, and of course to all in Poland and Ukraine who have more significant consequences to worry about.
Matroid bingo(\(\mathbb{M}\)). The requirements that no bingo card be empty, that everyone can win (no card has a subset of numbers of another card), and that no two players can win simultaneously (no union of two cards has a third card as a subset) turn out to match the axioms for the cycles in a matroid. It is not required that everyone have equal probability of winning, but the dual Fano matroid turns out to be particularly fair in this sense.
"I'll be on vacation so I won't be checking email.''
"I can't be at the meeting since I will be out of town''
Technology has made it so that:
a) You really CAN get email when you are on vacation.
b) You really CAN go to a meeting if you are out of town (if the meeting is on Zoom which is becoming more and more common). (My proofreader tells me that Zoom is spelled with a capital Z. I did not know that! The phrase I Googled is formally correct, though I googled is acceptable. I have never seen anyone say or write I Binged or I binged for searching, though I have seen I binged watched Babylon Five for example. I have never seen I Yahooed or I yahooed for search or for any other reason. Fun fact: the term Yahoo was coined by Jonathan Swift for use in the book Gulliver's Travels.)
Caveats:
1) You are on vacation! You DO NOT WANT to answer email!
2) You are out of town at a conference and the meeting is at the same time as a talk you want to go to.
3) There are too many meetings so it's good to have an excuse to not go to some.
Personal:
This is one issue where I may be LESS of a Luddite than Lance:
When Lance is on vacation, he DOES NOT get email.
When I am out of town, I DO get email, and respond to it. This first struck me when I was on a riverboat cruise in France and I got an email from my chairman asking if I would be on some committee (I said yes). I was more `in contact' than people on campus who don't respond to email.
How we talk about things: My advisor told me he would be giving a talk in Zurich. I azoomed he meant a talk on Zoom. He actually meant in person. Fortunately it was recorded so I didn't have to get up at 5:00 a.m. to see it. (My spellcheck thinks azoomed is not a word. It is correct. For now.)
By gasarch
"I'll be on vacation so I won't be checking email.''
"I can't be at the meeting since I will be out of town''
Technology has made it so that:
a) You really CAN get email when you are on vacation.
b) You really CAN go to a meeting if you are out of town (if the meeting is on Zoom which is becoming more and more common). (My proofreader tells me that Zoom is spelled with a capital Z. I did not know that! The phrase I Googled is formally correct, though I googled is acceptable. I have never seen anyone say or write I Binged or I binged for searching, though I have seen I bingedwatched Babylon Five for example. I have never seen I Yahooed or I yahooed for search or for any other reason. Fun fact: the term Yahoo was coined by Jonathan Swift for use in the book Gulliver'sTravels.)
Caveats:
1) You are on vacation! You DO NOT WANT to answer email!
2) You are out of town at a conference and the meeting is at the same time as a talk you want to go to.
3) There are too many meetings so it's good to have an excuse to not go to some.
Personal:
This is one issue where I may be LESS of a Luddite than Lance:
When Lance is on vacation, he DOES NOT get email.
When I am out of town, I DO get email, and respond to it. This first struck me when I was on a riverboat cruise in France and I got an email from my chairman asking if I would be on some committee (I said yes). I was more `in contact' than people on campus who don't respond to email.
How we talk about things: My advisor told me he would be giving a talk in Zurich. I azoomed he meant a talk on Zoom. He actually meant in person. Fortunately it was recorded so I didn't have to get up at 5:00 a.m. to see it. (My spellcheck thinks azoomed is not a word. It is correct. For now.)
In this blog post, we will talk about some recent advances in algorithms for approximately solving Shapley Games. What is a Shapley Game? At an intuitive level, Shapley games capture the idea of extending one-shot 2-player games to be occurring over multiple stages. Explicitly, Shapley games are played on an underlying state space . At each , the two players can each choose one of actions. Based on their choices and , the first player receives a reward (and the second player receives ) and the game moves to state with probability . Furthermore, at each time step there is a probability that the game ends (thus, ). The goal of each player is to maximize their earnings. These games were introduced by [Shapley’53], where he also proved that when , the Shapley game has a value: that is, this maximum exists. Furthermore, this value can be characterized as the solution to a specific fixed point equation: defining to be the optimal payoff of a two-player game on the payoff matrix , the value of a Shapley Game is the unique vector satisfying for all (here, ). Intuitively, this makes sense: a player’s expected payoff at a given state is [...]
In this blog post, we will talk about some recent advances in algorithms for approximately solving Shapley Games.
What is a Shapley Game?
At an intuitive level, Shapley games capture the idea of extending one-shot 2-player games to be occurring over multiple stages.
Explicitly, Shapley games are played on an underlying state space . At each , the two players can each choose one of actions. Based on their choices and , the first player receives a reward (and the second player receives ) and the game moves to state with probability . Furthermore, at each time step there is a probability that the game ends (thus, ). The goal of each player is to maximize their earnings.
These games were introduced by [Shapley’53], where he also proved that when , the Shapley game has a value: that is, this maximum exists.
Furthermore, this value can be characterized as the solution to a specific fixed point equation: defining to be the optimal payoff of a two-player game on the payoff matrix , the value of a Shapley Game is the unique vector satisfying for all (here, ). Intuitively, this makes sense: a player’s expected payoff at a given state is determined exactly by their current payoff and their future payoff .
We are often interested in the setting where is exponentially small (in fact, it was later proven that Shapley games have a value when but we will not focus on this case).
Connecting Shapley Games to Fixed Point Theorems
As we talked about above, the value of a Shapley Game is the unique vector satisfying for all . If we define to be the vector consisting of the right hand side over all $\latex v\in V$, then it turns out that in addition to being polynomial-time computable, actually satisfies two special properties:
Monotonicity: for every ,
Contraction: for every ,
Later, we will also care about defining a contraction property for discrete functions: in this case, we loosen the constraint to be (else, all values are actually equal)
By Tarski’s Fixed Point Theorem, every monotone function has a fixed point; and by Banach’s Fixed Point Theorem, every contracting function also has a fixed point.
For our algorithms, we will not be interested in the exact Shapley value, but just an -approximation of it. To define this, let and .
Then, [EPRY’20] constructs a (discrete) monotone contraction such that
A query to requires one query to an oracle for .
Given any with , we can construct in polynomial time an such that .
satisfies that . This last condition is an implementation detail which will make some of the later exposition simpler.
With this reduction in mind, the challenge for approximately solving Shapley Games has just become one of finding monotone/contracting/both fixed points of a function over . In the next few sections, we will talk about some recent algorithms for accomplishing this.
It’s important to note which factors are important for the runtime and query and complexity here: we will often consider and to be “reasonable” (since this is the size of the state space and the bit complexity of the input, respectively). In a reasonable application, we would expect to generally be fairly small, likely .
Complexity Implications
Before describing algorithms for approximately solving Shapley Games, let’s take a look at the complexity landscape surrounding it.
Above is a diagram of the relevant complexity classes surrounding Shapley Games. These are, in order:
PPAD: A prototypical complete problem for PPAD is End-Of-Line: Given an (exponentially large) directed graph consisting of lines and cycles and a start point of a line, find the end of one of the lines. Two famous examples of problems complete for PPAD are finding (approximate) Nash Equilibria and Brouwer Fixed Points (Given a compact domain and a continuous function , find an such that ).
PLS (Polynomial Local Search): A prototypical complete problem for PLS is the following: given an (exponentially large) DAG and a potential function which only decreases along directed edges, find a local optimum. It is believed that neither PLS nor PPAD are subsets of each other.
CLS (Continuous Local Search): An example complete problem for CLS is Gradient Descent. It is also known that (shown in [FGHS’22]).
UEOPL (Unique End of Potential Line): There is a hidden class not in the above diagram: EOPL (End Of Potential Line). This marries the prototypical complete problems for PPAD and PLS by adding a potential function to End-Of-Line. Building on this, UEOPL asks for there to be exactly one line (and hence exactly one solution). By definition, this lies within .
From first principles, it is true that computing the (approximate) Shapley values lies both within PPAD and PLS (and hence within CLS), by noticing that it is a special case of Brouwer’s Fixed Point Theorem and admits the potential function , respectively. Furthermore, by Shapley’s Theorem, we know that there is a unique solution. Recently, [BFGMS’25] showed that computing approximate Shapley Values is within UEOPL. More generally, they showed that computing a fixed point of any monotone contraction is within UEOPL.
Algorithms
Inefficient Algorithms
Let’s begin by “forgetting” the contracting constraint and just trying to find a fixed point of a monotone . A simple algorithm for this task is to consider the sequence of iterates . Since is monotone, , and for all , it follows that there must be a repeat in this sequence. Unfortunately, the query complexity of this algorithm is . Since we are often interested in the setting where and are exponentially small, this is too slow.
In the opposite direction, suppose we just knew that was contracting, and not monotone. In this case, we can find an -approximate fixed point of directly by starting at an arbitrary point and considering the sequence which will require iterations and is also too slow.
On the other hand, exciting new work by [CLY’24] gave an algorithm with query complexity for the task when is just contracting. Unfortunately, the runtime of this algorithm depends on factors of at-least (there is a brute-force grid search over between each query).
By contrast, in the upcoming algorithms, we will have the property that the “external” runtime is at most some times the query complexity. Here, by external runtime, we mean the work in between oracle calls to .
We will now describe some algorithms for computing fixed points of monotone contractions. The current state of the art is an algorithm by [BFGMS’25] that takes queries to to find such a fixed point. Here, we will present a simplified version of this algorithm that takes queries to find this fixed point.
First Pass: Monotone Fixed Point Algorithms
On the path to faster algorithms, let’s begin with . Here, we know that and . We can then binary search for a fixed point, preserving the invariant that and at each iteration. This takes queries to .
Similarly, we can do a recursive -layer binary search to find a fixed point when is -dimensional, which requires queries to .
To improve this algorithm, let’s decompose it into two parts: a base case and a gluing theorem.
The base case here is solving in queries.
The “gluing theorem” says that if we can find a fixed point of a -dimensional in time , then we can find a fixed point of a -dimensional in time .
One road to improving the runtime of this algorithm is to improve the base case. That is, is there some fixed constant where we can find a fixed point of a -dimensional in queries?
Recent work in [BPR’25] has given a lower bound of for all , and there is a natural lower bound for . However, we can do better for , as shown in [FPS’22]:
Given a monotone , there is an algorithm which takes queries and outputs an for which .
Immediately, this implies an algorithm taking queries for finding a fixed point of a -dimensional . However, this is not the end of the story, as we can also derive a more general gluing theorem, also shown in [FPS’22]:
If we can find fixed points of dimensional s in query complexity respectively, then we can find the fixed point of a dimensional in query complexity .
Together, these imply an algorithm running in time for finding a fixed point.
Gluing Theorem
Let’s begin by discussing a variant of the gluing theorem from [BFGMS’25]. In particular, suppose that we have oracles and for the and dimensional monotone contraction problems, respectively.
As a first pass, consider giving to the function : in other words, call on the slice where the first coordinates are fixed to be and return the result of calling on this fixed point. Naively, this seems reasonable: is guaranteed to return a fixed point and hence when returns a fixed point in the first coordinates it must be the case that we know its fixed part in the last coordinates.
The issue, however is that is not monotone nor contracting: for example, suppose that was just the identity function: now, is free to return any point in on each run. To fix this, we will follow [BFGMS’25] and suppose that, magically, and both return the Least Fixed Point (LFP) of their input function (by Tarski’s Theorem, the set of fixed points form a sublattice so there exists an LFP: the meet of all of the fixed points).
Proof
We claim that this is sufficient to force to be a monotone contraction. To prove this, suppose we have two queries and , and suppose that and . We show the two necessary facts:
If , then .
It is true that (we prove this when , which can then be extended by induction)
To prove the first fact, we claim that for every such that , there exists a with such that , and that a similar statement holds in reverse (i.e., given a we can find with similar properties). The key observation is that , where the last inequality follows from .
Thus, we may consider the sequence . Each of these is upper bounded by and they form an increasing sequence, so one of the values among them must yield a fixed point . We can do a similar argument in the reverse direction, so this implies that when we also have . Furthermore, this also implies that .
Now, suppose and are incomparable. Then, compute (the meet of the two) and (the join of the two) which satisfy . It follows that if and are the least fixed points for and (and, as before, and are the fixed points we are looking for), then and thus . Hence, we are done.
With this in mind, the final question is: how can we find a Least Fixed Point? If were just monotone, then [EPRY’20] showed that this was NP-Hard. It turns out that when is -dimensional, there is a reduction from [BFGMS’25] that gives us the LFP with constantly many extra queries. We now have that the query complexity of gluing the two instances requires queries to .
We will briefly describe the parts of the base case algorithm from [FPS’22] that we will later use to inform our algorithm for monotone contractions.
To describe the base case algorithm, we need the following definition:
Given a function , we let and .
Finding a fixed point is equivalent to finding a point in . With this definition in mind, we can break up the [FPS’22] base case algorithm into two steps:
For a fixed , find some vector with in queries.
Binary search on to find a fixed point.
Overall we run the first step times which gives the final number of queries.
Brief Aside: Gluing Up & Down Points
Before discussing the [BFGMS’25] result, it’s worth mentioning that it is also possible to write a gluing theorem which uses just the first step of the above base case: that is, given oracles which compute either an Up or Down point (given a fixed coordinate), glue them together to find either an Up or Down point of a -dimensional instance. This result was shown in [CL’22] and immediately gives an algorithm running in time and queries .
The Power of Monotone Contractions
We are finally ready to bring everything together to describe our algorithm. The key idea is to strip wasteful work from the above base case. In particular, when we search for an Up or Down point along a particular slice , we are often redoing similar work (for example, we may have gained some information telling us that there is no Up/Down point in a given region of the grid, so there is no use re-searching there).
We will apply this idea to re-use work from prior iterations, so that the total amortized cost of the binary searches comes out to . In [BFGMS’25], they do this directly on -dimensional instances. In this overview, we will instead show how to compute a LFP of a -dimensional monotone contraction in queries, which, combined with the above gluing theorem, yields the desired query complexity.
We will require two properties to hold for our :
: recall that we have this for free from the [EPRY’20] reduction.
If then there exists no other with ; and similarly for . Equivalently, each -dimensional slice of has a unique fixed point.
We can achieve this as follows: if and , then set (else, set it to ). We can do the same in the direction. In this way, a consecutive sequence of fixed points will all move down except for the first instance.
Since each -dimensional slice of now has a unique fixed point, let’s define to be the unique fixed point for a given , and similarly define .
With this in mind, we can plot these functions:
Here, the blue line corresponds to and the red line corresponds to (we have also increased the bounds so that hits both the top and bottom edge). In fact, we can also say more: the salmon-colored region is exactly the Up set and the green region is exactly the Down set, and where the two lines meet is the set of fixed points!
Note that both and have slope at most in their respective directions, which suggests the following: if and , then , and similarly (but in the opposite direction) for the Down set. The reasoning for this is simply the observation that the distance between the two lines is non-increasing.
From this, we can derive our final algorithm: for a given , conduct a binary search to find either an Up or Down point (we are guaranteed at most one, unless there is a fixed point), but keep track of the interval which contains the whole Up/Down slice along that value. In future binary searches, reuse this interval (shifted appropriately by ) instead of starting with . In this way, the total number of queries is since over the course of the algorithm we do at most two full binary searches (one for Up and one for Down points).
Open Problems
There are a wealth of open problems left here, but we’ll mention two.
What is the true complexity of computing fixed points of monotone, contracting, and monotone contracting functions? This includes both the query complexity and the runtime, as currently we have a large gap between lower and upper bounds.
Are there other properties of Shapley Games that allow us to get faster approximate algorithms beyond just using monotonicity and contraction?
Acknowledgements: I would like to thank my quals committee: Nima Anari, Aviad Rubinstein, and Tselil Schramm for the useful feedback on my quals talk and some suggestions on this blog post. I would also like to thank Spencer Compton for valuable comments on this blog post.
References
[BFGMS’25] Batziou, E., Fearnley, J., Gordon, S., Mehta, R., & Savani, R. (2025, June). Monotone Contractions. In Proceedings of the 57th Annual ACM Symposium on Theory of Computing (pp. 507-517).
[BPR’25] Brânzei, S., Phillips, R., & Recker, N. (2025). Tarski Lower Bounds from Multi-Dimensional Herringbones. arXiv preprint arXiv:2502.16679.
[CL’22] Chen, X., & Li, Y. (2022, July). Improved upper bounds for finding tarski fixed points. In Proceedings of the 23rd ACM Conference on Economics and Computation (pp. 1108-1118).
[CLY’24] Chen, X., Li, Y., & Yannakakis, M. (2024, June). Computing a Fixed Point of Contraction Maps in Polynomial Queries. In Proceedings of the 56th Annual ACM Symposium on Theory of Computing (pp. 1364-1373).
[EPRY’20] Etessami, K., Papadimitriou, C., Rubinstein, A., & Yannakakis, M. (2020). Tarski’s Theorem, Supermodular Games, and the Complexity of Equilibria. In 11th Innovations in Theoretical Computer Science Conference (ITCS 2020) (pp. 18-1). Schloss Dagstuhl–Leibniz-Zentrum für Informatik.
[FGHS’22] Fearnley, J., Goldberg, P., Hollender, A., & Savani, R. (2022). The complexity of gradient descent: CLS= PPAD∩ PLS. Journal of the ACM, 70(1), 1-74.
[FPS’22] Fearnley, J., Pálvölgyi, D., & Savani, R. (2022). A faster algorithm for finding Tarski fixed points. ACM Transactions on Algorithms (TALG), 18(3), 1-23.
[Shapley’53] Shapley, L. S. (1953). Stochastic games. Proceedings of the national academy of sciences, 39(10), 1095-1100.
Authors: Alexandru Cojocaru, Juan Garay, Qipeng Liu, Fang Song
We give novel lifting theorems for security games in the quantum random
oracle model (QROM) in Noisy Intermediate-Scale Quantum (NISQ) settings such as
the hybrid query model, the noisy oracle and the bounded-depth models. We
provide, for the first time, a hybrid lifting theorem for hybrid algorithms
that can perform both quantum and classical queries, as well as a lifting
theorem for quantum algorithms with access to noisy oracles or bounded quantum
depth.
At the core of our results lies a novel measure-and-reprogram framework,
called hybrid coherent measure-and-reprogramming, tailored specifically for
hybrid algorithms. Equipped with the lifting theorem, we are able to prove
directly NISQ security and complexity results by calculating a single
combinatorial quantity, relying solely on classical reasoning.
As applications, we derive the first direct product theorems in the average
case, in the hybrid setting-i.e., an enabling tool to determine the hybrid
hardness of solving multi-instance security games. This allows us to derive in
a straightforward manner the NISQ hardness of various security games, such as
(i) the non-uniform hardness of salted games, (ii) the hardness of specific
cryptographic tasks such as the multiple instance version of one-wayness and
collision-resistance, and (iii) uniform or non-uniform hardness of many other
games.
We give novel lifting theorems for security games in the quantum random
oracle model (QROM) in Noisy Intermediate-Scale Quantum (NISQ) settings such as
the hybrid query model, the noisy oracle and the bounded-depth models. We
provide, for the first time, a hybrid lifting theorem for hybrid algorithms
that can perform both quantum and classical queries, as well as a lifting
theorem for quantum algorithms with access to noisy oracles or bounded quantum
depth.
At the core of our results lies a novel measure-and-reprogram framework,
called hybrid coherent measure-and-reprogramming, tailored specifically for
hybrid algorithms. Equipped with the lifting theorem, we are able to prove
directly NISQ security and complexity results by calculating a single
combinatorial quantity, relying solely on classical reasoning.
As applications, we derive the first direct product theorems in the average
case, in the hybrid setting-i.e., an enabling tool to determine the hybrid
hardness of solving multi-instance security games. This allows us to derive in
a straightforward manner the NISQ hardness of various security games, such as
(i) the non-uniform hardness of salted games, (ii) the hardness of specific
cryptographic tasks such as the multiple instance version of one-wayness and
collision-resistance, and (iii) uniform or non-uniform hardness of many other
games.
Authors: Alexandru Cojocaru, Juan Garay, Qipeng Liu, Fang Song
We give a tighter lifting theorem for security games in the quantum random
oracle model. At the core of our main result lies a novel measure-and-reprogram
framework that we call coherent reprogramming. This framework gives a tighter
lifting theorem for query complexity problems, that only requires purely
classical reasoning. As direct applications of our lifting theorem, we first
provide a quantum direct product theorem in the average case - i.e., an
enabling tool to determine the hardness of solving multi-instance security
games. This allows us to derive in a straightforward manner the hardness of
various security games, for example (i) the non-uniform hardness of salted
games, (ii) the hardness of specific cryptographic tasks such as the multiple
instance version of one-wayness and collision-resistance, and (iii) uniform or
non-uniform hardness of many other games.
We give a tighter lifting theorem for security games in the quantum random
oracle model. At the core of our main result lies a novel measure-and-reprogram
framework that we call coherent reprogramming. This framework gives a tighter
lifting theorem for query complexity problems, that only requires purely
classical reasoning. As direct applications of our lifting theorem, we first
provide a quantum direct product theorem in the average case - i.e., an
enabling tool to determine the hardness of solving multi-instance security
games. This allows us to derive in a straightforward manner the hardness of
various security games, for example (i) the non-uniform hardness of salted
games, (ii) the hardness of specific cryptographic tasks such as the multiple
instance version of one-wayness and collision-resistance, and (iii) uniform or
non-uniform hardness of many other games.
We study the problem of partitioning a polygon into the minimum number of
subpolygons using cuts in predetermined directions such that each resulting
subpolygon satisfies a given width constraint. A polygon satisfies the
unit-width constraint for a set of unit vectors if the length of the orthogonal
projection of the polygon on a line parallel to a vector in the set is at most
one. We analyze structural properties of the minimum partition numbers,
focusing on monotonicity under polygon containment. We show that the minimum
partition number of a simple polygon is at least that of any subpolygon,
provided that the subpolygon satisfies a certain orientation-wise convexity
with respect to the polygon. As a consequence, we prove a partition analogue of
Bang's conjecture about coverings of convex regions in the plane: for any
partition of a convex body in the plane, the sum of relative widths of all
parts is at least one. For any convex polygon, there exists a direction along
which an optimal partition is achieved by parallel cuts. Given such a
direction, an optimal partition can be computed in linear time.
We study the problem of partitioning a polygon into the minimum number of
subpolygons using cuts in predetermined directions such that each resulting
subpolygon satisfies a given width constraint. A polygon satisfies the
unit-width constraint for a set of unit vectors if the length of the orthogonal
projection of the polygon on a line parallel to a vector in the set is at most
one. We analyze structural properties of the minimum partition numbers,
focusing on monotonicity under polygon containment. We show that the minimum
partition number of a simple polygon is at least that of any subpolygon,
provided that the subpolygon satisfies a certain orientation-wise convexity
with respect to the polygon. As a consequence, we prove a partition analogue of
Bang's conjecture about coverings of convex regions in the plane: for any
partition of a convex body in the plane, the sum of relative widths of all
parts is at least one. For any convex polygon, there exists a direction along
which an optimal partition is achieved by parallel cuts. Given such a
direction, an optimal partition can be computed in linear time.
Authors: Michelle Döring, Jan Fehse, Tobias Friedrich, Paula Marten, Niklas Mohrin, Kirill Simonov, Farehe Soheil, Jakob Timm, Shaily Verma
The Vehicle Routing Problem (VRP) is a popular generalization of the
Traveling Salesperson Problem. Instead of one salesperson traversing the entire
weighted, undirected graph $G$, there are $k$ vehicles available to jointly
cover the set of clients $C \subseteq V(G)$. Every vehicle must start at one of
the depot vertices $D \subseteq V(G)$ and return to its start. Capacitated
Vehicle Routing (CVRP) additionally restricts the route of each vehicle by
limiting the number of clients it can cover, the distance it can travel, or
both.
In this work, we study the complexity of VRP and the three variants of CVRP
for several parameterizations, in particular focusing on the treewidth of $G$.
We present an FPT algorithm for VRP parameterized by treewidth. For CVRP, we
prove paraNP- and $W[\cdot]$-hardness for various parameterizations, including
treewidth, thereby rendering the existence of FPT algorithms unlikely. In turn,
we provide an XP algorithm for CVRP when parameterized by both treewidth and
the vehicle capacity.
The Vehicle Routing Problem (VRP) is a popular generalization of the
Traveling Salesperson Problem. Instead of one salesperson traversing the entire
weighted, undirected graph $G$, there are $k$ vehicles available to jointly
cover the set of clients $C \subseteq V(G)$. Every vehicle must start at one of
the depot vertices $D \subseteq V(G)$ and return to its start. Capacitated
Vehicle Routing (CVRP) additionally restricts the route of each vehicle by
limiting the number of clients it can cover, the distance it can travel, or
both.
In this work, we study the complexity of VRP and the three variants of CVRP
for several parameterizations, in particular focusing on the treewidth of $G$.
We present an FPT algorithm for VRP parameterized by treewidth. For CVRP, we
prove paraNP- and $W[\cdot]$-hardness for various parameterizations, including
treewidth, thereby rendering the existence of FPT algorithms unlikely. In turn,
we provide an XP algorithm for CVRP when parameterized by both treewidth and
the vehicle capacity.
Authors: Andreas Bluhm, Matthias C. Caro, Francisco Escudero Gutiérrez, Aadil Oufkir, Cambyse Rouzé
In this work, we study the problems of certifying and learning quantum Ising
Hamiltonians. Our main contributions are as follows:
Certification of Ising Hamiltonians. We show that certifying an Ising
Hamiltonian in normalized Frobenius norm via access to its time-evolution
operator requires only $\widetilde O(1/\varepsilon)$ time evolution. This
matches the Heisenberg-scaling lower bound of $\Omega(1/\varepsilon)$ up to
logarithmic factors. To our knowledge, this is the first nearly-optimal
algorithm for testing a Hamiltonian property. A key ingredient in our analysis
is the Bonami Lemma from Fourier analysis.
Learning Ising Gibbs states. We design an algorithm for learning Ising Gibbs
states in trace norm that is sample-efficient in all parameters. In contrast,
previous approaches learned the underlying Hamiltonian (which implies learning
the Gibbs state) but suffered from exponential sample complexity in the inverse
temperature.
Certification of Ising Gibbs states. We give an algorithm for certifying
Ising Gibbs states in trace norm that is both sample and time-efficient,
thereby solving a question posed by Anshu (Harvard Data Science Review, 2022).
Finally, we extend our results on learning and certification of Gibbs states
to general $k$-local Hamiltonians for any constant $k$.
In this work, we study the problems of certifying and learning quantum Ising
Hamiltonians. Our main contributions are as follows:
Certification of Ising Hamiltonians. We show that certifying an Ising
Hamiltonian in normalized Frobenius norm via access to its time-evolution
operator requires only $\widetilde O(1/\varepsilon)$ time evolution. This
matches the Heisenberg-scaling lower bound of $\Omega(1/\varepsilon)$ up to
logarithmic factors. To our knowledge, this is the first nearly-optimal
algorithm for testing a Hamiltonian property. A key ingredient in our analysis
is the Bonami Lemma from Fourier analysis.
Learning Ising Gibbs states. We design an algorithm for learning Ising Gibbs
states in trace norm that is sample-efficient in all parameters. In contrast,
previous approaches learned the underlying Hamiltonian (which implies learning
the Gibbs state) but suffered from exponential sample complexity in the inverse
temperature.
Certification of Ising Gibbs states. We give an algorithm for certifying
Ising Gibbs states in trace norm that is both sample and time-efficient,
thereby solving a question posed by Anshu (Harvard Data Science Review, 2022).
Finally, we extend our results on learning and certification of Gibbs states
to general $k$-local Hamiltonians for any constant $k$.
In this paper, we study the class $\mathtt{cstPP}$ of operations
$\mathtt{op}: \mathbb{N}^k\to\mathbb{N}$, of any fixed arity $k\ge 1$,
satisfying the following property: for each fixed integer $d\ge 1$, there
exists an algorithm for a RAM machine which, for any input integer $N\ge 2$, -
pre-computes some tables in $O(N)$ time, - then reads $k$ operands
$x_1,\ldots,x_k1$, or conversely, is reduced
to $N^{\varepsilon}$, for any positive $\varepsilon<1$ (provided the set of
primitive operation includes $+$, $\mathtt{div}$ and $\mathtt{mod}$). To
complete the picture, we demonstrate that the $\mathtt{cstPP}$ class
degenerates if the preprocessing time reduces to $N^{o(1)}$.
In this paper, we study the class $\mathtt{cstPP}$ of operations
$\mathtt{op}: \mathbb{N}^k\to\mathbb{N}$, of any fixed arity $k\ge 1$,
satisfying the following property: for each fixed integer $d\ge 1$, there
exists an algorithm for a RAM machine which, for any input integer $N\ge 2$, -
pre-computes some tables in $O(N)$ time, - then reads $k$ operands
$x_1,\ldots,x_k1$, or conversely, is reduced
to $N^{\varepsilon}$, for any positive $\varepsilon<1$ (provided the set of
primitive operation includes $+$, $\mathtt{div}$ and $\mathtt{mod}$). To
complete the picture, we demonstrate that the $\mathtt{cstPP}$ class
degenerates if the preprocessing time reduces to $N^{o(1)}$.
Authors: Amira Abbas, Nunzia Cerrato, Francisco Escudero Gutiérrez, Dmitry Grinko, Francesco Anna Mele, Pulkit Sinha
We study the problem of learning Hamiltonians $H$ that are $s$-sparse in the
Pauli basis, given access to their time evolution. Although Hamiltonian
learning has been extensively investigated, two issues recur in much of the
existing literature: the absence of matching lower bounds and the use of
mathematically convenient but physically opaque error measures.
We address both challenges by introducing two physically motivated distances
between Hamiltonians and designing a nearly optimal algorithm with respect to
one of these metrics. The first, time-constrained distance, quantifies
distinguishability through dynamical evolution up to a bounded time. The
second, temperature-constrained distance, captures distinguishability through
thermal states at bounded inverse temperatures.
We show that $s$-sparse Hamiltonians with bounded operator norm can be
learned in both distances with $O(s \log(1/\epsilon))$ experiments and
$O(s^2/\epsilon)$ evolution time. For the time-constrained distance, we further
establish lower bounds of $\Omega((s/n)\log(1/\epsilon) + s)$ experiments and
$\Omega(\sqrt{s}/\epsilon)$ evolution time, demonstrating near-optimality in
the number of experiments.
As an intermediate result, we obtain an algorithm that learns every Pauli
coefficient of $s$-sparse Hamiltonians up to error $\epsilon$ in
$O(s\log(1/\epsilon))$ experiments and $O(s/\epsilon)$ evolution time,
improving upon several recent results.
The source of this improvement is a new isolation technique, inspired by the
Valiant-Vazirani theorem (STOC'85), which shows that NP is as easy as detecting
unique solutions. This isolation technique allows us to query the time
evolution of a single Pauli coefficient of a sparse Hamiltonian--even when the
Pauli support of the Hamiltonian is unknown--ultimately enabling us to recover
the Pauli support itself.
We study the problem of learning Hamiltonians $H$ that are $s$-sparse in the
Pauli basis, given access to their time evolution. Although Hamiltonian
learning has been extensively investigated, two issues recur in much of the
existing literature: the absence of matching lower bounds and the use of
mathematically convenient but physically opaque error measures.
We address both challenges by introducing two physically motivated distances
between Hamiltonians and designing a nearly optimal algorithm with respect to
one of these metrics. The first, time-constrained distance, quantifies
distinguishability through dynamical evolution up to a bounded time. The
second, temperature-constrained distance, captures distinguishability through
thermal states at bounded inverse temperatures.
We show that $s$-sparse Hamiltonians with bounded operator norm can be
learned in both distances with $O(s \log(1/\epsilon))$ experiments and
$O(s^2/\epsilon)$ evolution time. For the time-constrained distance, we further
establish lower bounds of $\Omega((s/n)\log(1/\epsilon) + s)$ experiments and
$\Omega(\sqrt{s}/\epsilon)$ evolution time, demonstrating near-optimality in
the number of experiments.
As an intermediate result, we obtain an algorithm that learns every Pauli
coefficient of $s$-sparse Hamiltonians up to error $\epsilon$ in
$O(s\log(1/\epsilon))$ experiments and $O(s/\epsilon)$ evolution time,
improving upon several recent results.
The source of this improvement is a new isolation technique, inspired by the
Valiant-Vazirani theorem (STOC'85), which shows that NP is as easy as detecting
unique solutions. This isolation technique allows us to query the time
evolution of a single Pauli coefficient of a sparse Hamiltonian--even when the
Pauli support of the Hamiltonian is unknown--ultimately enabling us to recover
the Pauli support itself.
Authors: Alexander Taveira Blomenhofer, Benjamin Lovitz
We propose a linear-time algorithm to compute low-rank Chow decompositions.
Our algorithm can decompose concise symmetric 3-tensors in n variables of Chow
rank n/3. The algorithm is pencil based, hence it relies on generalized
eigenvalue computations. We also develop sub-quadratic time algorithms for
higher order Chow decompositions, and Chow decompositions of 3-tensors into
products of linear forms which do not lie on the generic orbit. In particular,
we obtain a sub-quadratic-time algorithm for decomposing a symmetric 3-tensor
into a linear combination of W-tensors.
We propose a linear-time algorithm to compute low-rank Chow decompositions.
Our algorithm can decompose concise symmetric 3-tensors in n variables of Chow
rank n/3. The algorithm is pencil based, hence it relies on generalized
eigenvalue computations. We also develop sub-quadratic time algorithms for
higher order Chow decompositions, and Chow decompositions of 3-tensors into
products of linear forms which do not lie on the generic orbit. In particular,
we obtain a sub-quadratic-time algorithm for decomposing a symmetric 3-tensor
into a linear combination of W-tensors.
Authors: Simen Storesund, Kristian Valset Aars, Robin Dietrich, Nicolai Waniek
Efficient planning and sequence selection are central to intelligence, yet
current approaches remain largely incompatible with biological computation.
Classical graph algorithms like Dijkstra's or A* require global state and
biologically implausible operations such as backtracing, while reinforcement
learning methods rely on slow gradient-based policy updates that appear
inconsistent with rapid behavioral adaptation observed in natural systems.
We propose a biologically plausible algorithm for shortest-path computation
that operates through local spike-based message-passing with realistic
processing delays. The algorithm exploits spike-timing coincidences to identify
nodes on optimal paths: Neurons that receive inhibitory-excitatory message
pairs earlier than predicted reduce their response delays, creating a temporal
compression that propagates backwards from target to source. Through analytical
proof and simulations on random spatial networks, we demonstrate that the
algorithm converges and discovers all shortest paths using purely timing-based
mechanisms. By showing how short-term timing dynamics alone can compute
shortest paths, this work provides new insights into how biological networks
might solve complex computational problems through purely local computation and
relative spike-time prediction. These findings open new directions for
understanding distributed computation in biological and artificial systems,
with possible implications for computational neuroscience, AI, reinforcement
learning, and neuromorphic systems.
Efficient planning and sequence selection are central to intelligence, yet
current approaches remain largely incompatible with biological computation.
Classical graph algorithms like Dijkstra's or A* require global state and
biologically implausible operations such as backtracing, while reinforcement
learning methods rely on slow gradient-based policy updates that appear
inconsistent with rapid behavioral adaptation observed in natural systems.
We propose a biologically plausible algorithm for shortest-path computation
that operates through local spike-based message-passing with realistic
processing delays. The algorithm exploits spike-timing coincidences to identify
nodes on optimal paths: Neurons that receive inhibitory-excitatory message
pairs earlier than predicted reduce their response delays, creating a temporal
compression that propagates backwards from target to source. Through analytical
proof and simulations on random spatial networks, we demonstrate that the
algorithm converges and discovers all shortest paths using purely timing-based
mechanisms. By showing how short-term timing dynamics alone can compute
shortest paths, this work provides new insights into how biological networks
might solve complex computational problems through purely local computation and
relative spike-time prediction. These findings open new directions for
understanding distributed computation in biological and artificial systems,
with possible implications for computational neuroscience, AI, reinforcement
learning, and neuromorphic systems.
Quantum circuits composed of CNOT and $R_z$ are fundamental building blocks
of many quantum algorithms, so optimizing the synthesis of such quantum
circuits is crucial. We address this problem from a theoretical perspective by
studying the graphic parity network synthesis problem. A graphic parity network
for a graph $G$ is a quantum circuit composed solely of CNOT gates where each
edge of $G$ is represented in the circuit, and the final state of the wires
matches the original input. We aim to synthesize graphic parity networks with
the minimum number of gates, specifically for quantum algorithms addressing
combinatorial optimization problems with Ising formulations. We demonstrate
that a graphic parity network for a connected graph with $n$ vertices and $m$
edges requires at least $m+n-1$ gates. This lower bound can be improved to
$m+\Omega(m) = m+\Omega(n^{1.5})$ when the shortest cycle in the graph has a
length of at least five. We complement this result with a simple randomized
algorithm that synthesizes a graphic parity network with expected $m +
O(n^{1.5}\sqrt{\log n})$ gates. Additionally, we begin exploring connected
graphs that allow for graphic parity networks with exactly $m+n-1$ gates. We
conjecture that all such graphs belong to a newly defined graph class.
Furthermore, we present a linear-time algorithm for synthesizing minimum
graphic parity networks for graphs within this class. However, this graph class
is not closed under taking induced subgraphs, and we show that recognizing it
is $\textsf{NP}$-complete, which is complemented with a fixed-parameter
tractable algorithm parameterized by the treewidth.
Quantum circuits composed of CNOT and $R_z$ are fundamental building blocks
of many quantum algorithms, so optimizing the synthesis of such quantum
circuits is crucial. We address this problem from a theoretical perspective by
studying the graphic parity network synthesis problem. A graphic parity network
for a graph $G$ is a quantum circuit composed solely of CNOT gates where each
edge of $G$ is represented in the circuit, and the final state of the wires
matches the original input. We aim to synthesize graphic parity networks with
the minimum number of gates, specifically for quantum algorithms addressing
combinatorial optimization problems with Ising formulations. We demonstrate
that a graphic parity network for a connected graph with $n$ vertices and $m$
edges requires at least $m+n-1$ gates. This lower bound can be improved to
$m+\Omega(m) = m+\Omega(n^{1.5})$ when the shortest cycle in the graph has a
length of at least five. We complement this result with a simple randomized
algorithm that synthesizes a graphic parity network with expected $m +
O(n^{1.5}\sqrt{\log n})$ gates. Additionally, we begin exploring connected
graphs that allow for graphic parity networks with exactly $m+n-1$ gates. We
conjecture that all such graphs belong to a newly defined graph class.
Furthermore, we present a linear-time algorithm for synthesizing minimum
graphic parity networks for graphs within this class. However, this graph class
is not closed under taking induced subgraphs, and we show that recognizing it
is $\textsf{NP}$-complete, which is complemented with a fixed-parameter
tractable algorithm parameterized by the treewidth.
We revisit Approximate Graph Propagation (AGP), a unified framework which
captures various graph propagation tasks, such as PageRank, feature propagation
in Graph Neural Networks (GNNs), and graph-based Retrieval-Augmented Generation
(RAG). Our work focuses on the settings of dynamic graphs and dynamic
parameterized queries, where the underlying graphs evolve over time (updated by
edge insertions or deletions) and the input query parameters are specified on
the fly to fit application needs. Our first contribution is an interesting
observation that the SOTA solution, AGP-Static, can be adapted to support
dynamic parameterized queries; however several challenges remain unresolved.
Firstly, the query time complexity of AGP-Static is based on an assumption of
using an optimal algorithm for subset sampling in its query algorithm.
Unfortunately, back to that time, such an algorithm did not exist; without such
an optimal algorithm, an extra $O(\log^2 n)$ factor is required in the query
complexity, where $n$ is the number of vertices in the graphs. Secondly,
AGP-Static performs poorly on dynamic graphs, taking $O(n\log n)$ time to
process each update. To address these challenges, we propose a new algorithm,
AGP-Static++, which is simpler yet reduces roughly a factor of $O(\log^2 n)$ in
the query complexity while preserving the approximation guarantees of
AGP-Static. However, AGP-Static++ still requires $O(n)$ time to process each
update. To better support dynamic graphs, we further propose AGP-Dynamic, which
achieves $O(1)$ amortized time per update, significantly improving the
aforementioned $O(n)$ per-update bound, while still preserving the query
complexity and approximation guarantees. Last, our comprehensive experiments
validate the theoretical improvements: compared to the baselines, our algorithm
achieves speedups of up to $177\times$ on update time and $10\times$ on query
efficiency.
We revisit Approximate Graph Propagation (AGP), a unified framework which
captures various graph propagation tasks, such as PageRank, feature propagation
in Graph Neural Networks (GNNs), and graph-based Retrieval-Augmented Generation
(RAG). Our work focuses on the settings of dynamic graphs and dynamic
parameterized queries, where the underlying graphs evolve over time (updated by
edge insertions or deletions) and the input query parameters are specified on
the fly to fit application needs. Our first contribution is an interesting
observation that the SOTA solution, AGP-Static, can be adapted to support
dynamic parameterized queries; however several challenges remain unresolved.
Firstly, the query time complexity of AGP-Static is based on an assumption of
using an optimal algorithm for subset sampling in its query algorithm.
Unfortunately, back to that time, such an algorithm did not exist; without such
an optimal algorithm, an extra $O(\log^2 n)$ factor is required in the query
complexity, where $n$ is the number of vertices in the graphs. Secondly,
AGP-Static performs poorly on dynamic graphs, taking $O(n\log n)$ time to
process each update. To address these challenges, we propose a new algorithm,
AGP-Static++, which is simpler yet reduces roughly a factor of $O(\log^2 n)$ in
the query complexity while preserving the approximation guarantees of
AGP-Static. However, AGP-Static++ still requires $O(n)$ time to process each
update. To better support dynamic graphs, we further propose AGP-Dynamic, which
achieves $O(1)$ amortized time per update, significantly improving the
aforementioned $O(n)$ per-update bound, while still preserving the query
complexity and approximation guarantees. Last, our comprehensive experiments
validate the theoretical improvements: compared to the baselines, our algorithm
achieves speedups of up to $177\times$ on update time and $10\times$ on query
efficiency.
such that for every 
we have![\displaystyle \min_{x \in [0, 2pi]}\sum_{a\in A}\cos(ax)\leq \Omega(|A|^{\gamma}).](https://s0.wp.com/latex.php?latex=%5Cdisplaystyle+%5Cmin_%7Bx+%5Cin+%5B0%2C+2pi%5D%7D%5Csum_%7Ba%5Cin+A%7D%5Ccos%28ax%29%5Cleq+%5COmega%28%7CA%7C%5E%7B%5Cgamma%7D%29.&bg=ffffff&fg=333333&s=0&c=20201002)
with 
edges and no clique of size 
has a cut of size at least 
for some 
. This proves a weak version of a celebrated conjecture of Alon, Bollob’as, Krivelevich, and Sudakov.
be a finite set of 
positive integers, and consider the cosine sum 
. We prove that there exists an absolute constant 
such that 
is the answer. 
and some 
the some of cosines 
is smaller than 
for arbitrary large real 
. This was solved by M. Uchiyama and S. Uchiyama in 1960. In 1965 Sarvadaman Chowla asked if putting 
. Achieving 
followed from the resolution of a well-known problem by Littlewood and breaking the 
barrier was achieved by Bourgain and greatly improved by Rusza to 
.
integers his work is related to the same Littlewood problem mentioned above, and to a work by Bourgain. The interesting story behind it was told in a Quanta Magazine 
. At each 
, the two players can each choose one of 
actions. Based on their choices 
and 
, the first player receives a reward ![A_v[i,j]\in \mathbb R](https://s0.wp.com/latex.php?latex=A_v%5Bi%2Cj%5D%5Cin+%5Cmathbb+R&bg=ffffff&fg=000000&s=0&c=20201002)
(and the second player receives ![-A_v[i,j]](https://s0.wp.com/latex.php?latex=-A_v%5Bi%2Cj%5D&bg=ffffff&fg=000000&s=0&c=20201002)
) and the game moves to state 
with probability ](https://s0.wp.com/latex.php?latex=P_v%5Bi%2Cj%5D%28u%29&bg=ffffff&fg=000000&s=0&c=20201002)
. Furthermore, at each time step there is a probability 
that the game ends (thus,  = 1 - q](https://s0.wp.com/latex.php?latex=%5Csum_%7Bu%5Cin+V%7D+P_v%5Bi%2Cj%5D%28u%29+%3D+1+-+q&bg=ffffff&fg=000000&s=0&c=20201002)
). The goal of each player is to maximize their earnings.
, the Shapley game has a value: that is, this maximum exists.
to be the optimal payoff of a two-player game on the payoff matrix 
, the value of a Shapley Game is the unique vector 
satisfying 
for all 
). Intuitively, this makes sense: a player’s expected payoff at a given state 
is determined exactly by their current payoff 
and their future payoff 
.
but we will not focus on this case).
to be the vector consisting of the right hand side over all $\latex v\in V$, then it turns out that in addition to being polynomial-time computable, 
actually satisfies two special properties:
, 
, 
(else, all values are actually equal)
-approximation of it. To define this, let 
and 
.![F: [n]^d \rightarrow [n]^d](https://s0.wp.com/latex.php?latex=F%3A+%5Bn%5D%5Ed+%5Crightarrow+%5Bn%5D%5Ed&bg=ffffff&fg=000000&s=0&c=20201002)
such that
requires one query to an oracle for 
, we can construct in polynomial time an 
such that 
.
. This last condition is an implementation detail which will make some of the later exposition simpler.![[n]^d](https://s0.wp.com/latex.php?latex=%5Bn%5D%5Ed&bg=ffffff&fg=000000&s=0&c=20201002)
. In the next few sections, we will talk about some recent algorithms for accomplishing this.
and 
to be “reasonable” (since this is the size of the state space and the bit complexity of the input, respectively). In a reasonable application, we would expect 
.
and a continuous function 
, find an 
).
(shown in [
.
, respectively. Furthermore, by Shapley’s Theorem, we know that there is a unique solution. Recently, [![F : [n]^d\rightarrow [n]^d](https://s0.wp.com/latex.php?latex=F+%3A+%5Bn%5D%5Ed%5Crightarrow+%5Bn%5D%5Ed&bg=ffffff&fg=000000&s=0&c=20201002)
. A simple algorithm for this task is to consider the sequence of iterates 
. Since 
, and 
for all 
. Since we are often interested in the setting where 
which will require 
iterations and is also too slow.
for the task when 
(there is a brute-force grid search over 
times the query complexity. Here, by external runtime, we mean the work in between oracle calls to 
queries to 
queries to find this fixed point.
. Here, we know that 
and 
. We can then binary search for a fixed point, preserving the invariant that 
and 
at each iteration. This takes 
queries to 
queries to 
, then we can find a fixed point of a 
-dimensional 
.
where we can find a fixed point of a 
-dimensional 
queries?
for all 
, and there is a natural 
lower bound for 
, as shown in [![F: [n]^3\rightarrow [n]^3](https://s0.wp.com/latex.php?latex=F%3A+%5Bn%5D%5E3%5Crightarrow+%5Bn%5D%5E3&bg=ffffff&fg=000000&s=0&c=20201002)
, there is an algorithm which takes 
queries and outputs an 
queries for finding a fixed point of a 
dimensional 
respectively, then we can find the fixed point of a 
dimensional 
.
for finding a fixed point.
and 
for the 
and 
dimensional monotone contraction problems, respectively.
: in other words, call 
is not monotone nor contracting: for example, suppose that ![[n]^{d_2}](https://s0.wp.com/latex.php?latex=%5Bn%5D%5E%7Bd_2%7D&bg=ffffff&fg=000000&s=0&c=20201002)
on each run. To fix this, we will follow [
and 
. We show the two necessary facts:
, then 
.
(we prove this when 
, which can then be extended by induction)
such that 
, there exists a 
with 
such that 
, and that a similar statement holds in reverse (i.e., given a 
we can find 
with similar properties). The key observation is that 
, where the last inequality follows from 
.
. Each of these is upper bounded by 
and they form an increasing sequence, so one of the values among them must yield a fixed point 
. We can do a similar argument in the reverse direction, so this implies that when 
we also have 
.
(the meet of the two) and 
(the join of the two) which satisfy 
. It follows that if 
and 
are the least fixed points for 
and 
(and, as before, 
and thus 
. Hence, we are done.
-dimensional, there is a reduction from [
queries to ![\text{Up}(F) = \{x\in [n]^d: f(x) \ge x\}](https://s0.wp.com/latex.php?latex=%5Ctext%7BUp%7D%28F%29+%3D+%5C%7Bx%5Cin+%5Bn%5D%5Ed%3A+f%28x%29+%5Cge+x%5C%7D&bg=ffffff&fg=000000&s=0&c=20201002)
and ![\text{Down}(F) = \{x\in [n]^d : f(x) \le x\}](https://s0.wp.com/latex.php?latex=%5Ctext%7BDown%7D%28F%29+%3D+%5C%7Bx%5Cin+%5Bn%5D%5Ed+%3A+f%28x%29+%5Cle+x%5C%7D&bg=ffffff&fg=000000&s=0&c=20201002)
.
. With this definition in mind, we can break up the [
, find some vector 
with 
in 
.
-dimensional instances. In this overview, we will instead show how to compute a LFP of a ![F: [n]^2\rightarrow [n]^2](https://s0.wp.com/latex.php?latex=F%3A+%5Bn%5D%5E2%5Crightarrow+%5Bn%5D%5E2&bg=ffffff&fg=000000&s=0&c=20201002)
:
: recall that we have this for free from the [
then there exists no other 
with 
; and similarly for 
-dimensional slice of 
and 
, then set 
(else, set it to 
). We can do the same in the 
to be the unique fixed point 
.
![\text{Up}(f) \cap \{x = i\} = [a_i, b_i]](https://s0.wp.com/latex.php?latex=%5Ctext%7BUp%7D%28f%29+%5Ccap+%5C%7Bx+%3D+i%5C%7D+%3D+%5Ba_i%2C+b_i%5D&bg=ffffff&fg=000000&s=0&c=20201002)
and 
, then ![\text{Up}(f) \cap \{x = j\} \subseteq [a_i + (j - i), b_i + (j - i)]](https://s0.wp.com/latex.php?latex=%5Ctext%7BUp%7D%28f%29+%5Ccap+%5C%7Bx+%3D+j%5C%7D+%5Csubseteq+%5Ba_i+%2B+%28j+-+i%29%2C+b_i+%2B+%28j+-+i%29%5D&bg=ffffff&fg=000000&s=0&c=20201002)
, and similarly (but in the opposite direction) for the Down set. The reasoning for this is simply the observation that the distance between the two lines is non-increasing.
) instead of starting with ![[1, n]](https://s0.wp.com/latex.php?latex=%5B1%2C+n%5D&bg=ffffff&fg=000000&s=0&c=20201002)
. In this way, the total number of queries is