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// ****************************************************************
// *   Software Failure.  Press left mouse button to continue.    *
// *             Guru Meditation #00000000.00000000               *
// ****************************************************************

What is this?

This is Guru Meditation's entry to the ICFP 2014 Contest.

Who we are

Some Statistics

  • 494 lines of Scala;
  • 570 lines of LambdaLisp;
  • 712 lines of Ghc;
  • 35 hours of work from Friday to Sunday.

Quick-start

Run sbt assembly to generate the compiler for the "lambda-man" and the address solver for "ghc". Use the included script llc to generate the bot we've submitted (greedy-bot) based on the functional programming language LambdaLisp™ (specifically created for ICFPC 2014):

./llc src/main/lambdalisp/greedy-bot.ll --bot

The --bot flag informs the compiler to generate code that loads the maze during startup. The code will be dumped to stdout. To generate the ghosts code:

./lhc src/main/ghc/ghost-fright.ghc

Again, the resulting code will be dumped to stdout.

Here's an example random bot written in LambdaLisp:

(include prelude.ll)
(include random.ll)

(randomnot: [v m]
   (let ((r (mod (random) m)))
     (tif (= r v)
          (recur v m)
          r)))

(main: [state]
  (let ((map (car state))
        (lambdaman (car (cdr state)))
        (ghosts (car (cdr (cdr state))))
        (fruit (cdr (cdr (cdr state)))))
     (let ((location (car (cdr lambdaman)))
          (direction (car (cdr (cdr lambdaman)))))

        (if (or (or (or (and (= direction 0) (= (nnth map (- (cdr location) 1) (car location)) 0))
                        (and (= direction 1) (= (nnth map (cdr location) (+ (car location) 1)) 0)))
                        (and (= direction 2) (= (nnth map (+ (cdr location) 1) (car location)) 0)))
                        (and (= direction 3) (= (nnth map (cdr location) (- (car location) 1)) 0)))
         (cons 0 (randomnot direction 4))
         (cons 0 direction)))))

(cons 0 main)

And the generated General Compute Coprocessor assembly can be seen here.

Solution

Friday

After a quick read of the implementation (and a somewhat befuddled feeling caused by the realisation that we would be implementing two compilers for two unknown processors in two days), we started designing a compiler (transpiler?) for a simple Lisp, which we called LambdaLisp, that targeted the General Compute Coprocessor. Some theoretical questions over what would be possible to do with the GCC were debated over a Sushi lunch, followed by a coordinated attack on the implementation of LambdaLisp (which was pretty much following through the specification). In order to have a global namespace, we created an initial environment frame of configurable size filled with zeros. Whenever we were transpiling LambdaLisp to GCC, we kept a stack of names to environment positions for the local namespaces and a single map of names to environment positions for the global namespace. That way, the position of the environment for the global namespace was always given by the size of the stack of local environments. This allowed us to declare some global methods and variables that were available for the whole LambdaLisp program without producing a gigantic LET. One of the things we probably overlooked was not annotating the GCC generated code with flags of what and why was happening, until very late in the last day; something that could have probably helped us debug the transpiler. Lesson learned for next time. We called the day when we started implementing our LambdaLisp prelude.

Saturday

Saturday turned out to be an exciting day. Two major things happened: first, we had the compiler "mostly" working, up to a point where we were able to start developing a basic standard library for the newly created LambdaLisp. A true "prelude" started gaining considerable weight. This standard library included combinators for lists (e.g. fold, map, forall, filter), as well as data structures (e.g. queues, binary-trees, heaps).

The second major thing is that, because we were forced upon purely-functional implementations of these data-structures (since we found no way to have an O(1) random memory access in the GCC), we eventually recalled we had one book in our desks that could help us in this job: the famous "Purely Functional Data Structures" by Chris Okasaki. It was a delight to see our queues were already following his own guidelines.

We ended Saturday by perhaps giving too much love and tender to our LambdaLisp implementation, since we were already discussing syntactic shortcuts to things like lists, closures, c[a|d]r, and so on. But our morale was getting pretty high by then. We called it a day when a topological sort for solving .ll dependencies became our focus.

Sunday

A day of mixed feelings. Our focus was clearly becoming the AI, and two days later we were still completely disregarding GHC. We implemented the A* search algorithm, which was used for path-finding by the LambdaMan. Our strategy for the LambdaMan was as greedy as possible: try to get to the position that provided the highest amount of points immediately, while avoiding the ghosts. This was not the smartest of strategies, since it would be useful to keep power pills uneaten while it wasn't possible to reach ghosts in time, but still provided decent scores for the Hall of Fame maps (we were #1 in the ghostbusters map for a while).

Ghostbusters Map

By the time we got our strategy going, our luck turned around. We started struggling with the limit of instructions per program. We relied heavily on our standard library but our methods were sub-optimal regarding the produced instructions size. For example, we initially started by flattening the input map in order to insert it in a binary tree for quicker index-based access and this operation by itself was enough to reach the instruction limit in larger maps. Consumed by a mix of tiredness and frustration, in a faint glimpse of hope, we decided to use the map size as the deciding factor of whether we would use the previously described strategy or a completely random one. This means that in a lot of the judge's maps a random strategy was in use.

Only by the end of the contest did we start to implement a ghost AI. We implemented a simple assembler for the GHost CPU that allowed us to use labels and it would generate programs with the addressing calculated. The ghost AI goes in the direction of the LambdaMan, and runs away from him if freight mode was enabled. It uses the pledge algorithm for path-finding. It wasn't our finest moment, and we learned another valuable lesson: don't put all your eggs in the same basket.

Conclusion

All in all, it was a fun contest. We flirted for a while with the possibility of having GCC emulating GHC and using it for the AI. We naively even talked about Monte Carlo Tree Search and stuff like that, before we realised we could never overcome the instruction limit of the GHC in time to rely on such "advanced" strategies. We certainly look forward for the 2015 edition.

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