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In another thread, Joe Fitzsimons asked about "the best current lower bounds on 3SAT."

I'd like to go the other way: What's the best current upper bounds on 3SAT? In other words, what is the time complexity of the most efficient SAT solver?

In particular, is it conceivable to find a sub-exponential (yet super-polynomial) algorithm for SAT?

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    $\begingroup$ I don't know about analytic results, but you can find experimental results here baldur.iti.uka.de/sat-race-2010/results.html (see the "HTML" links) $\endgroup$
    – Radu GRIGore
    Commented Sep 7, 2010 at 19:10
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    $\begingroup$ this question title is a bit misleading, because of the existence of this question: cstheory.stackexchange.com/questions/1295/sat-solver-download . I think you might rephrase as 'Best Upper Bounds on SAT' ? $\endgroup$
    – Suresh Venkat
    Commented Sep 25, 2010 at 13:30
  • $\begingroup$ @Suresh: The question you are referring to relates to "#SAT", while this one corresponds to SAT. In addition, that question was asked about a week after this one. Anyhow, do you still suggest changing this ones' title? $\endgroup$
    – Sadeq Dousti
    Commented Sep 25, 2010 at 16:44
  • $\begingroup$ yes, because a "SAT Solver" is a specific well known object - an actual codebase for solving SAT. Google will get confused and redirect people looking for code over here :). $\endgroup$
    – Suresh Venkat
    Commented Sep 25, 2010 at 18:00
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    $\begingroup$ Regarding the motivation for this question, I thought several people had tried SAT solvers on the 17x17 instances. It seems to be the frontier of what can be handled with a SAT solver. You could instead try a parallel solver, but I was under the impression based on Bill Gasarch's posts that you would need a large-scale effort. You could also apply an SMT solver with a suitable theory, or use a constraint solver that implements a global constraint that has an efficient propagator. In each of these cases the new idea would be to express an important property that is hard to do using clauses. $\endgroup$
    – András Salamon
    Commented Sep 27, 2010 at 17:19

9 Answers 9

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The best algorithm for 3-SAT now has numerical upper bound $O^{*}(1.306995^n)$ on unique-3-SAT and on general-3-SAT it is also fastest but now the specific values have not been analyzed yet.

Authors say they hope the improved bounds for unique-3-SAT also apply directly to 3-SAT by using essentially the arguments of Hertli.

The algorithm is described in this paper:

Thomas Dueholm Hansen, Haim Kaplan, Or Zamir, Uri Zwick, Faster k-SAT algorithms using biased-PPSZ, 2019

Simply speaking, it adds bias to the PPSZ algorithm to let some literals have a higher, lower or equal probability to turn to some value.

In the paper, they say that the derandomization of this algorithm may be not very hard and moreover, they believe this algorithm can achieve $O^{*}(1.30331^n)$ for 3-SAT.

For future work, they say there is a more challenging way to obtian further improvements by guessing more varibles biasedly without using a set of disjoint clauses as a scaffolding that simplifies analysis.

In the paper, the problem whether bound for k-SAT can be of form ${2^{\left(1 - \frac{\omega (1)}{k}\right)n}}$ is proposed by authors and is believed to be more important than just giving a better constant bound for 3-SAT.

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There are two kinds of "best" SAT solvers, one for theory, one for practice.

Theory

randomized $O(1.32113^n)$ for 3SAT.

randomized $O(1.321^n)$ for 3SAT.

deterministic $O(1.439^n)$ for 3SAT.

Practice

Check SAT conference for competition results for each year.

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  • $\begingroup$ I found a link to Iwama et al. paper. So, is $O(1.32113^n)$ really the latest and best result for solving SAT up until now? $\endgroup$
    – Sadeq Dousti
    Commented Sep 9, 2010 at 15:51
  • $\begingroup$ @ Sadeq: I think so, but just for 3-SAT, not SAT. $\endgroup$
    – Tian Liu
    Commented Sep 10, 2010 at 0:20
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    $\begingroup$ Now the best algorithm is in $O(1.321^n)$ time by Timon Hertli, Robin A. Moser and Dominik Scheder. $\endgroup$
    – Tian Liu
    Commented Sep 28, 2010 at 5:42
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    $\begingroup$ Yet another update: in FOCS 2011, Timon Hertli (arxiv.org/abs/1103.2165) proved that the PPSZ algorithm solves every 3SAT instance in $1.308^n$ time. $\endgroup$
    – Ryan Williams
    Commented Jan 7, 2012 at 18:59
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I am not aware of any zero-error randomized algorithms (or coNE/Eadvice algorithms,
for that matter) for SAT that have better bounds than known deterministic algorithms,
regardless of whether or not there is promised to be at most one satisfying assignment.


"Problem 3-SAT is deterministically solvable in time $\overset{\sim}{O}(1.3303^n)$."


"For a uniquely satisfiable 3-CNF (resp. 4-CNF) on $n$ variables, the satisfying assignment
can be found in deterministic running time at most $O\hspace{.02 in}(1.3071^n)$ (resp. $O\hspace{.02 in}(1.4699^n)$)."


  1. "There exists a randomized algorithm for 3-SAT with
    one-sided error that runs in time $O\hspace{.02 in}(1.30704^n)$."
  2. "There exists a randomized algorithm for 4-SAT with
    one-sided error that runs in time $O\hspace{.02 in}(1.46899^n)$."


"There is a randomized algorithm for unique-3-SAT such that for $\: \epsilon = 1\hspace{-0.03 in}\big/\hspace{-0.06 in}\left(\hspace{-0.03 in}10^{\hspace{.02 in}24}\hspace{-0.04 in}\right) \:$ and
$S$ the real number that lets the previous paper's runtime bound for 3-SAT be expressed
as $\: O\hspace{-0.04 in}\left(2^{(S+o(1))\cdot n}\right) \:$, $\;$ the current paper's algorithm runs in time $\: O\hspace{-0.04 in}\left(2^{(S-\epsilon+o(1))\cdot n}\right)$ ."


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Schoening's algorithm is a probabilistic algorithm for k-SAT with running time $O(a^n)$, where $a = 2(k-1)/k$. This results in an $O(1.33334^n)$ algorithm for 3SAT, an $O(1.5^n)$ algorithm for 4SAT, etc.

The algorithm has also been (almost completely) derandomized by Moser and Scheder, who give a deterministic algorithm for solving kSAT running time $O((a+\epsilon)^n)$ where $a$ is the same constant as before, and $\epsilon>0$ can be made arbitrarily small.

Note: In this answer the big Oh notation hides poly(n) factors. I wanted to use the $O^*$ notation, but it isn't rendering properly.

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    $\begingroup$ Why do you say "almost completely"? Did I miss something in the paper? $\endgroup$
    – András Salamon
    Commented Sep 7, 2010 at 23:45
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    $\begingroup$ There is a deterministic $O((2 - \frac{2}{k + 1})^n)$ algorithm for k-SAT by eight people, so please forgive me not mentioning all of them. Here is the link: linkinghub.elsevier.com/retrieve/pii/S0304397501001748. So for $k = 3$ we have $O(1.5^n)$ and it is not as good as other bounds for 3-SAT presented here, but for k-SAT it is the best, as far as I know. $\endgroup$
    – Grigory Yaroslavtsev
    Commented Sep 8, 2010 at 0:06
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    $\begingroup$ I said "almost completely" just to indicate that there's an epsilon factor there. I guess one would expect that a complete derandomization achieves the same run time (upto polynomial factors). Or maybe that's unreasonable to expect. $\endgroup$
    – Robin Kothari
    Commented Sep 8, 2010 at 1:26
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    $\begingroup$ @Grigory Yaroslavtsev: Isn't the Moser-Scheder deterministic algorithm for kSAT that I mentioned faster that the one you quoted? Am I missing something? $\endgroup$
    – Robin Kothari
    Commented Sep 8, 2010 at 1:28
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    $\begingroup$ I was just worried about this $\epsilon$ in your notation, so it is faster indeed. It looks like the paper appeared on arXiv just a few days ago: arxiv.org/PS_cache/arxiv/pdf/1008/1008.4067v1.pdf, so no wonder I didn't know about it. $\endgroup$
    – Grigory Yaroslavtsev
    Commented Sep 8, 2010 at 3:15
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As was already mentioned, if you are interested in theoretical running time guarantees, this question is a duplicate.

But I'd like to point out that if you really want to solve a concrete problem (like the colouring problem that you mentioned), I think that it makes absolutely no sense at all to study theoretical upper bounds.

Even though you wanted to avoid "engineering" aspects, I'd suggest that you just take some popular SAT solvers, try them out, and see what happens (most of them can read the same DIMACS file format, so it is easy to try different solvers). You may have both positive and negative surprises. Recently I had a family of SAT instances; a bunch of instances with tens of thousands of variables and more than one million clauses turned out to be easy to solve, while seemingly much simpler instances with just hundreds of variables and thousands of clauses were far too difficult for any solver that I tried.

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    $\begingroup$ In addition to Jukka's summary, it is also worth noting that there are two main kinds of SAT solvers: those based on survey propagation, which work well for random SAT instances, and those which use clause learning combined with unit resolution, which tend to work well to discover combinatorial structure. These have quite different behaviour. The worst cases for SAT solvers tend to be instances that are not satisfiable, but where the space of nogoods has complex structure that does not allow much pruning. Unfortunately instances from combinatorics tend to be of this kind. $\endgroup$
    – András Salamon
    Commented Sep 27, 2010 at 17:10
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deterministic $O(1.308^n)$ for 3SAT.

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  • $\begingroup$ I assume that when somebody comes up with a better upper bound they would cite this paper. There has been only once citation to this paper, which is "A Satisfiability Algorithm and Average-Case Hardness for Formulas over the Full Binary Basis" And they seem to talk about only certain types of formulas. Therefore, this seems to be the best Upper Bound thus far. $\endgroup$
    – Tayfun Pay
    Commented Feb 9, 2014 at 1:52
  • $\begingroup$ @TayfunPay : $\:$ The bottom paper in my answer cites that paper. $\;\;\;\;$ $\endgroup$
    – user6973
    Commented Feb 9, 2014 at 8:03
  • $\begingroup$ @RickyDemer Uhuh! is it a better bound than this? Notation is not so clear to me. $\endgroup$
    – Tayfun Pay
    Commented Feb 10, 2014 at 2:09
  • $\begingroup$ @TayfunPay : $\:$ Yes, and you can hunt through the two papers as described in the following. $\:$ On page 5 of the general 3-SAT paper, they give the value of $S_3$, report the PPSZ algorithm's runtime for unique k-SAT in terms of $S_k$, and say that they have the same bound for general k-SAT. $\:$ At the top of page 11, that paper says their algorithm gives the same bound as PPSZ, which means they did not show anything more than I mentioned in my previous sentence. $\:$ (continued ...) $\hspace{.35 in}$ $\endgroup$
    – user6973
    Commented Feb 10, 2014 at 5:33
  • $\begingroup$ (... continued) $\:$ On page 2 of the unique 3-SAT paper, they give the value of $S$ and say that their algorithm gives a bound that is better than $2^{S\cdot n}$ by an explicit exponential amount. $\:$ Since $S$ from my previous sentence is equal to $S_3$ from the sentence before that, the unique 3-SAT paper's bound is exponentially better than the general 3-SAT paper's bound. $\;\;\;$ $\endgroup$
    – user6973
    Commented Feb 10, 2014 at 5:34
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It is impossible for 3SAT to have sub-exponential algorithms unless the exponential time hypothesis is false.

randomized algorithm with expected running time $O({1.324}^n)$ for 3SAT.

randomized algorithm with expected running time $O({1.32216}^n)$ for 3SAT.

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    $\begingroup$ Isn’t that a tautology? $\endgroup$
    – Tsuyoshi Ito
    Commented Sep 7, 2010 at 19:19
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    $\begingroup$ Yes, that is a tautology: The exponential time hypothesis (ETH) is that 3SAT, the satisfiability problem of Boolean formulas in conjunctive normal form with at most three literals per clause and with n variables, cannot be solved in time $2^{o(n)}$. (See: wikipedia). $\endgroup$
    – Sadeq Dousti
    Commented Sep 7, 2010 at 19:59
  • $\begingroup$ The work of Kazuo Iwama et al. (2004) is newer than that of Schoening's (1999). I wonder if even more recent results are available. $\endgroup$
    – Sadeq Dousti
    Commented Sep 7, 2010 at 20:14
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    $\begingroup$ To avoid possibility of confusion, my last comment refers to the first sentence of the answer: “It is impossible for 3SAT to have sub-exponential algorithms unless the exponential time hypothesis (ETH) is false.” My understanding is that the exponential-time hypothesis is the very hypothesis stating that there is no algorithm for 3SAT whose running time is subexponential (i.e. 2^{o(n)}) in the number of variables. $\endgroup$
    – Tsuyoshi Ito
    Commented Sep 7, 2010 at 21:51
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    $\begingroup$ And to avoid further confusion, I will add that when Tsuyoshi posted his comment, the answer only contained that one sentence, which made his comment very appropriate. $\endgroup$
    – Robin Kothari
    Commented Sep 8, 2010 at 1:29
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This post deals with upper bounds on SAT. This one deals with best lower bounds. This link gives details of the annual competition comparing SAT solver implementations, which are all downloadable. For simplicity, you could start with SAT4J, a Java based library for SAT solving.

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  • $\begingroup$ Turns out this question was already asked before; I just didn't see it when I searched the website. Tian Liu's response on the upper bounds question is exactly what I was looking for. Thanks for the links, dave! $\endgroup$
    – Daniel Apon
    Commented Sep 27, 2010 at 14:55
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    $\begingroup$ This is evidence that I spend too much time here ;-) $\endgroup$
    – Dave Clarke
    Commented Sep 27, 2010 at 14:59
  • $\begingroup$ we're glad that you do :) $\endgroup$
    – Suresh Venkat
    Commented Sep 28, 2010 at 2:52
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    $\begingroup$ I'm not sure if I would recommend sat4J, not only it is significantly slower than the state-of-the-art but also somewhat more complex. It is true, however, that it is nicely customizable due to the object-oriented structure. MiniSat is very nicely written and 2.2 is state-of-the-art. $\endgroup$
    – Mikolas
    Commented Apr 7, 2011 at 7:55
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The best deterministic algorithm for 3-SAT now has upper bound 1.32793^n, see https://arxiv.org/abs/1804.07901 by Sixue Liu. Basically the upper bounds for all k-SAT have been improved in this paper.

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