I became interested in the idea of an AI for this game containing no hard-coded intelligence (i.e no heuristics, scoring functions etc). The AI should "know" only the game rules, and "figure out" the game play. This is in contrast to most AIs (like the ones in this thread) where the game play is essentially brute force steered by a scoring function representing human understanding of the game.
I found a simple yet surprisingly good playing algorithm: To determine the move for a given board, the AI plays the game til the end using random moves. This is done many times while keeping track of the end score. Then the average end score per starting move is calculated. The move with the highest score is chosen.
Using just 100 runs per move the AI achieves the 2048 tile 80% of the times and the 4096 tile 50% of the times. Using 10000 runs gets the 2048 tile 100%, 70% for 4096 tile, and about 1% for the 8192 tile.
See it in action
The best achieved score is shown here:
An interesting fact about this AI is that the random-play games are (unsurprisingly) quite bad, yet choosing the best (or least bad) move leads to very good game play: A typical AI game can reach 70000 points and last 3000 moves, yet the random-play runs yield an average of 340 extra points and only 40 moves before dying. (You can see this for yourself by running the AI and opening the debug console.)
This graph illustrates this point: The blue line shows the board score after each move. The red line shows the AI's best end game score at that point. In essence, the red values are "pulling" the blue values upwards towards them, as they are the AI's best guess. Note that the red line is just a tiny bit over the blue line at each point, yet the blue line continues to increase more and more.
I find this quite surprising, that the AI doesn't need to actually foresee good game play in order to chose the moves that produce it.
Searching later I found this algorithm might be classified as a Pure Monte Carlo Tree Search algorithm.
Implementation and Links
Later, in order to play around some more I used @nneonneo highly optimized infrastructure and implemented my version in C++. This version allows for up to 100000 runs per move and even 1000000 if you have the patience. Building instructions provided. It runs in the console and also has a remote-control to play the web version.
Surprisingly, increasing the number of runs does not drastically improve the game play. There seems to be a limit to this strategy at around 80000 points with the 4096 tile and all the smaller ones, very close to the achieving the 8192 tile. Increasing the number of runs from 100 to 100000 increases the odds of getting to around this score limit (from 5% to 40%) but not breaking through it.
Running 10000 runs with a temporary increase to 1000000 near critical positions managed to break this barrier less than 1% of the times achieving a max score of 129892 and a 8192 tile.
After implementing this algorithm I tried many improvements including using the min or max scores, or a combination of min,max,and avg. I also tried using depth: Instead of trying K runs per move, I tried K moves per move list of a given length ("up,up,left" for example) and selecting the first move of the best scoring move list.
Later I implemented a scoring tree that took into account the conditional probability of being able to play a move after a given move list.
However, none of these ideas showed any real advantage over the simple first idea. I left the code for these ideas commented out in the C++ code.
I did add a "Deep Search" mechanism that increased the run number temporarily to 1000000 when any of the runs managed to accidentally reach the next highest tile. This offered a time improvement.
I'd be interested to hear if anyone has other improvement ideas that maintain the domain-independence of the AI.
2048 Variants and Clones
Just for fun, I've also implemented the AI as a bookmarklet, hooking into the game's controls. This allows the AI to work with the original game and many of its variants.
This is possible due to domain-independent nature of the AI. Some of the variants are quite distinct, such as the Hexagonal clone.