Game Description Language
Game Description Language, or GDL, is a logic programming language[1] designed by Michael Genesereth for general game playing in artificial intelligence, as part of the General Game Playing Project at Stanford University. GDL describes the state of a game as a series of facts, and the game mechanics as logical rules. GDL is hereby one of the alternative representations for game theoretic problems.[2]
Purpose of GDL
Quoted in an article in New Scientist, Genesereth pointed out that although Deep Blue can play chess at a grandmaster level, it is incapable of playing checkers at all because it is a specialized game player.[3] Both chess and checkers can be described in GDL. This enables general game players to be built that can play both of these games and any other game that can be described using GDL.
Specification
Syntax
GDL is a variant of Datalog, and the syntax is largely the same. It is usually given in prefix notation. Variables begin with "?
".[4]
Keywords
The following is the list of keywords in GDL, along with brief descriptions of their functions:
distinct
- This predicate is used to require that two terms be syntactically different.
does
- The predicate
does(?r,?m)
means that player (or role)?r
makes move?m
in the current game state.
goal
- The predicate
goal(?r,?n)
is used to define goal value?n
(usually a natural number between 0 and 100) for role?r
in the current state.
init
- This predicate refers to a true fact about the initial game state.
legal
- The predicate
legal(?r,?m)
means that?m
is a legal move for role?r
in the current state.
next
- This predicate refers to a true fact about the next game state.
role
- This predicate is used to add the name of a player.
terminal
- This predicate means that the current state is terminal.
true
- This predicate refers to a true fact about the current game state.
Rules
A game description in GDL provides complete rules for each of the following elements of a game.
Players
Facts that define the roles in a game. The following example is from a GDL description of the two-player game Tic-tac-toe:
(role xplayer) (role oplayer)
Initial state
Rules that entail all facts about the initial game state. An example is:
(init (cell 1 1 blank)) ... (init (cell 3 3 blank)) (init (control xplayer))
Legal moves
Rules that describe each move by the conditions on the current position under which it can be taken by a player. An example is:
(<= (legal ?player (mark ?m ?n))
(true (cell ?m ?n blank))
(true (control ?player)))
Game state update
Rules that describe all facts about the next state relative to the current state and the moves taken by the players. An example is:
(<= (next (cell ?m ?n x))
(does xplayer (mark ?m ?n)))
(<= (next (cell ?m ?n o))
(does oplayer (mark ?m ?n)))
Termination
Rules that describe the conditions under which the current state is a terminal one. An example is:
(<= terminal (line x)) (<= terminal (line o)) (<= terminal not boardopen)
Goal states
The goal values for each player in a terminal state. An example is:
(<= (goal xplayer 100)
(line x))
(<= (goal oplayer 0)
(line x))
Extensions
GDL-II
With GDL, one can describe finite games with an arbitrary numbers of players. However, GDL cannot describe games which contain an element of chance (for example, rolling dice) or games where players have incomplete information about the current state of the game (for example, in many card games the opponents' cards are not visible). GDL-II, the Game Description Language for Incomplete Information Games, extends GDL by two keywords that allow for the description of elements of chance and incomplete information:[5]
sees
- The predicate
sees(?r,?p)
means that role?r
perceives?p
in the next game state.
random
- This constant refers to a pre-defined player who chooses moves randomly.
The following is an example from a GDL-II description of the card game Texas hold 'em:
(<= (sees ?player ?card)
(does random (deal_face_down ?player ?card)))
(<= (sees ?r ?card)
(role ?r)
(does random (deal_river ?card)))
GDL-III
Michael Thielscher also created a further extension, GDL-III, a general game description language with imperfect information and introspection, that supports the specification of epistemic games — ones characterised by rules that depend on the knowledge of players.[6]
Other formalisms and languages for game representation
In classical game theory, games can be formalised in extensive and normal forms. For cooperative game theory, games are represented using characteristic functions. Some subclasses of games allow special representations in smaller sizes also known as succinct games. Some of the newer developments of formalisms and languages for representation of some subclasses of games or representations adjusted to the needs of interdisciplinary research are summarized as the following table.[7] Some of these alternative representations also encode time related aspects:
Name | Year | Means | Type of games | Time |
---|---|---|---|---|
Congestion game[8] | 1973 | functions | subset of n-person games, simultaneous moves | No |
Sequential form[9] | 1994 | matrices | 2-person games of imperfect information | No |
Timed games[10][11] | 1994 | functions | 2-person games | Yes |
Gala[12] | 1997 | logic | n-person games of imperfect information | No |
Graphical games[13][14] | 2001 | graphs, functions | n-person games, simultaneous moves | No |
Local effect games[15] | 2003 | functions | subset of n-person games, simultaneous moves | No |
Game Petri-nets[16] | 2006 | Petri net | deterministic n-person games, simultaneous moves | No |
Continuous games[17] | 2007 | functions | subset of 2-person games of imperfect information | Yes |
PNSI[18][19] | 2008 | Petri net | n-person games of imperfect information | Yes |
Action graph games[20] | 2012 | graphs, functions | n-person games, simultaneous moves | No |
Applications
A 2016 paper "describes a multilevel algorithm compiling a general game description in GDL into an optimized reasoner in a low level language".[21]
A 2017 paper uses GDL to model the process of mediating a resolution to a dispute between two parties, and presented an algorithm that uses available information efficiently to do so.[22]
References
- "Game Definition Language". games.stanford.edu.
- Tagiew, Rustam (2011). Averkin, Alexey N.; Ignatov, Dmitry I.; Mitra, Sushmita; Poelmans, Jonas (eds.). "Beyond Analytical Modeling, Gathering Data to Predict Real Agents' Strategic Interaction" [Soft Computing Applications and Knowledge Discovery] (PDF). CEUR Workshop Proceedings. Moscow, Russia. 758: 113–124.
- Biever, Celeste (2006-07-29). "Producing the ultimate game-playing bots - tech - 29 July 2006 - New Scientist Tech". Archived from the original on 11 August 2007.
- Love, N; Genesereth, M; Hinrichs, T (2006). "General game playing: game description language specification. Tech. Rep. LG-2006-01" (PDF). Stanford University. Stanford University, Stanford. Retrieved 1 July 2019.
- Thielscher, M (2010). Fox, M; Poole, D (eds.). "A general game description language for incomplete information games". Proceedings of the Twenty-Fourth AAAI Conference on Artificial Intelligence, AAAI 2010. Atlanta: AAAI Press. Retrieved 1 July 2019.
- Thielscher, Michael (2017). "GDL-III: A Description Language for Epistemic General Game Playing" (PDF). Proceedings of the Twenty-Sixth International Joint Conference on Artificial Intelligence. IJCAI. ISBN 978-0-9992411-0-3. Retrieved 1 July 2019.
- Tagiew, Rustam (3 May 2011). "If more than Analytical Modeling is Needed to Predict Real Agents' Strategic Interaction". arXiv:1105.0558 [cs.GT].
- Rosenthal, Robert W. (December 1973). "A class of games possessing pure-strategy Nash equilibria". International Journal of Game Theory. 2 (1): 65–67. doi:10.1007/BF01737559. S2CID 121904640.
- Koller, Daphne; Megiddo, Nimrod; von Stengel, Bernhard (1994). "Fast algorithms for finding randomized strategies in game trees". Proceedings of the twenty-sixth annual ACM symposium on Theory of computing - STOC '94. pp. 750–759. doi:10.1145/195058.195451. ISBN 0-89791-663-8. S2CID 1893272.
- Alur, Rajeev; Dill, David L. (April 1994). "A theory of timed automata". Theoretical Computer Science. 126 (2): 183–235. doi:10.1016/0304-3975(94)90010-8.
- Tomlin, C.J.; Lygeros, J.; Shankar Sastry, S. (July 2000). "A game theoretic approach to controller design for hybrid systems". Proceedings of the IEEE. 88 (7): 949–970. doi:10.1109/5.871303. S2CID 1844682.
- Koller, Daphne; Pfeffer, Avi (1997). "Representations and solutions for game-theoretic problems" (PDF). Artificial Intelligence. 94 (1–2): 167–215. doi:10.1016/S0004-3702(97)00023-4.
- Michael, Michael Kearns; Littman, Michael L. (2001). "Graphical Models for Game Theory". In UAI: 253–260. CiteSeerX 10.1.1.22.5705.
- Kearns, Michael; Littman, Michael L.; Singh, Satinder (7 March 2011). "Graphical Models for Game Theory". arXiv:1301.2281 [cs.GT].
- Leyton-Brown, Kevin; Tennenholtz, Moshe (2003). "Local-effect games". IJCAI'03: Proceedings of the 18th International Joint Conference on Artificial Intelligence: 772–777.
- Clempner, Julio (2006). "Modeling shortest path games with Petri nets: a Lyapunov based theory". International Journal of Applied Mathematics and Computer Science. 16 (3): 387–397. ISSN 1641-876X.
- Sannikov, Yuliy (September 2007). "Games with Imperfectly Observable Actions in Continuous Time" (PDF). Econometrica. 75 (5): 1285–1329. doi:10.1111/j.1468-0262.2007.00795.x.
- Tagiew, Rustam (December 2008). "Multi-Agent Petri-Games". 2008 International Conference on Computational Intelligence for Modelling Control & Automation. pp. 130–135. doi:10.1109/CIMCA.2008.15. ISBN 978-0-7695-3514-2. S2CID 16679934.
- Tagiew, Rustam (2009). "On Multi-agent Petri Net Models for Computing Extensive Finite Games". New Challenges in Computational Collective Intelligence. Studies in Computational Intelligence. Springer. 244: 243–254. doi:10.1007/978-3-642-03958-4_21. ISBN 978-3-642-03957-7.
- Bhat, Navin; Leyton-Brown, Kevin (11 July 2012). "Computing Nash Equilibria of Action-Graph Games". arXiv:1207.4128 [cs.GT].
- Kowalski, Jakub; Szykuła, Marek (2013). "Game Description Language Compiler Construction". AI 2013: Advances in Artificial Intelligence: 26th Australasian Joint Conference, Dunedin, New Zealand, December 1-6, 2013. Proceedings. pp. 234–245. Retrieved 1 July 2019.
- de Jonge, Dave; Trescak, Tomas; Sierra, Carles; Simoff, Simeon; López de Mántaras, Ramon (2017). "Using Game Description Language for mediated dispute resolution". AI & Society. Springer. 2017 (4): 767–784. doi:10.1007/s00146-017-0790-8. S2CID 22738517.