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The game 2048 has exploded in popularity since its release in February 2014. For a description of the game and discussion of optimal algorithms, see What is the optimal algorithm for the game 2048?. Here is the source code.

A blind algorithm for 2048 is one that cannot see the board; the only feedback the algorithm receives is whether or not an attempted slide occurred (we may suppose a blocked slide produces an audible beep). A blind algorithm is practically useful for getting started in 2048 without having to give the game your undivided attention.

Here is my specific question: is there a blind algorithm for 2048 that consistently does better than a mean score of 3500 in 10^6 trials? (only post an answer you have validated)

This is the performance of the LADDER algorithm, which may be notated as (LD* RD*)* (+U). That is, one loops over "left, down repeatedly until stuck, right, down repeated until stuck" and presses up iff left, right, and down are all blocked, which occurs iff the top row(s) are completely empty and the bottom row(s) are completely full. I call this algorithm LADDER because of the letters LDDR, and because I imagine climbing down ladders like Mario in Donkey Kong. The motivation for the algorithm is to maintain an increasing gradient from top to bottom of the board, similar to many of the non-blind algorithms.

Here is a histogram for 10^6 trials of LADDER colored by top tile on the final board with bin width 32 and mean 3478.1. I generated this data by simulating the game and algorithm in Python, using probability .9 that each new tile is a 2, as in the original game. You can't see the 1024 games at this vertical scale but they are sparsely distributed between 8000 and 16000. The fractal structure relates to the number of occurrences of the top tile, second-from-top tile, and so on. By comparison, random button mashing gave a mean of about 800 in 10^4 trials.

enter image description here

closed as too broad by Niklas B., Dukeling, David Eisenstat, Josh Caswell, random Mar 30 '14 at 20:08

Please edit the question to limit it to a specific problem with enough detail to identify an adequate answer. Avoid asking multiple distinct questions at once. See the How to Ask page for help clarifying this question. If this question can be reworded to fit the rules in the help center, please edit the question.

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    I don't see a specific question here. Possible answers will just be different strategies that people think are good, but that would not answer the question, since you ask for an optimal algorithm, so without a proof no answer fulfills that criterion. I think the same applies for the original question – Niklas B. Mar 30 '14 at 18:57
  • I appreciate your point Niklas B, and rephrased the more specific question as "Is there a blind algorithm that consistently does better 3500 in 10^6 trials?". I recognize this still falls short of proof, but I think it should still be reasonable to reach community consensus on a proposed better algorithm through simulation (which I expect is the best we can do here, though I'd love to be proven wrong). – Jonathan Bloom Mar 30 '14 at 19:15
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    I still feel your question is very unclear. First you ask about an optimal algorithm. Then you ask for an algorithm that does better than some specific other algorithm in randomly generated games for which you don't provide the generation framework. Then you say you want an algorithm does well for the start to mid-game, but your framework seems to measure the total score up to the end of the game. What this will turn out to be is a place where people propose different solutions and test them against each other. Stack Overflow is not for competitions. – Niklas B. Mar 30 '14 at 19:45
  • Isn't the generation framework specified for 2048? – Noah Snyder Mar 30 '14 at 19:57
  • @NoahSnyder I have no idea, but I also can't be expected to figure that out myself. Questions on Stack Overflow are supposed to be self-contained and minimal. – Niklas B. Mar 30 '14 at 20:00
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The most important in the 2048 game is to concentrate the high numbers along the borders and not in the middle. So a very good strategy is to put everything along the bottom as long as possible. Your LADDER algorithm does this, but I'd like to concentrate more on the left side and not switch to the right side completely. This is the algorithm in pseudo code:

while(true)
    {
    if (down)
        continue;
    elseif(left)
        continue;
    elseif (right)
        continue;
    else
        {
        up;
        down; //if forced to go up; go back down immediately
        }
    }

Using your convention this would be:

((D*L)*R)U

in words: go down as long as you can; if you cannot; go left; if you cannot go left; go right. You will rarely need to go up.

Since I won't have time shortly to implement this to use it 10⁶ times; I hope someone else can give the correct statisctics for this, but my guess is this will outperform your LADDER algorithm

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    You can be forced to go up (if every row is completely full). In such a situation the obvious strategy is up followed immediately by down. – Noah Snyder Mar 30 '14 at 22:40
  • Since the question has been put on hold, I've modified it to be more precise. As such, please validate that your algorithm meets the specified criteria, which will require implementing it and running it 1000000 times. – Jonathan Bloom Mar 30 '14 at 23:08
  • @Noah Snyder: you are right: going up will be last resort... – Chris Maes Mar 31 '14 at 5:49
  • @JonathanBloom I'd love to start implementing the whole thing to start validating and playing around, but I don't have the time for that. So please either validate my algorithm or give me a link where I can find your code... – Chris Maes Mar 31 '14 at 18:32

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