Tic-tac-toe explained

Italic Title:no
Tic-tac-toe
Other Names:
  • Noughts and Crosses
  • Xs and Os
Image Caption:A completed game of tic-tac-toe
Genre:Paper-and-pencil game
Players:2
Setup Time:Minimal
Playing Time:~1 minute
Random Chance:None
Skills:Strategy, tactics, observation

Tic-tac-toe (American English), noughts and crosses (Commonwealth English), or Xs and Os (Canadian or Irish English) is a paper-and-pencil game for two players who take turns marking the spaces in a three-by-three grid with X or O. The player who succeeds in placing three of their marks in a horizontal, vertical, or diagonal row is the winner. It is a solved game, with a forced draw assuming best play from both players.

Names

In American English, the game is known as "tic-tac-toe". It may also be spelled "tick-tack-toe", "tick-tat-toe", or "tit-tat-toe".[1] [2]

In Commonwealth English (particularly British, South African, Indian, Australian, and New Zealand English), the game is known as "noughts and crosses", alternatively spelled "naughts and crosses". This name derives from the shape of the marks in the game (i.e the X and O); "nought" is an older name for the number zero, while "cross" refers to the X shape. While the term "nought" is now less commonly used, the name "noughts and crosses" is still preferred over the American name "tic-tac-toe" in these countries.

Sometimes, tic-tac-toe (where players keep adding "pieces") and three men's morris (where pieces start to move after a certain number have been placed) are confused with each other.

Gameplay

Tic-tac-toe is played on a three-by-three grid by two players, who alternately place the marks X and O in one of the nine spaces in the grid.

In the following example, the first player (X) wins the game in seven steps:

There is no universally agreed rule as to who plays first, but in this article the convention that X plays first is used.

Players soon discover that the best play from both parties leads to a draw. Hence, tic-tac-toe is often played by young children who may not have discovered the optimal strategy.

Because of the simplicity of tic-tac-toe, it is often used as a pedagogical tool for teaching the concepts of good sportsmanship and the branch of artificial intelligence that deals with the searching of game trees. It is straightforward to write a computer program to play tic-tac-toe perfectly or to enumerate the 765 essentially different positions (the state space complexity) or the 26,830 possible games up to rotations and reflections (the game tree complexity) on this space.[3] If played optimally by both players, the game always ends in a draw, making tic-tac-toe a futile game.[4]

The game can be generalized to an m,n,k-game, in which two players alternate placing stones of their own color on an m-by-n board with the goal of getting k of their own color in a row. Tic-tac-toe is the 3,3,3-game.[5] Harary's generalized tic-tac-toe is an even broader generalization of tic-tac-toe. It can also be generalized as an nd game, specifically one in which n = 3 and d = 2. It can be generalised even further by playing on an arbitrary incidence structure, where rows are lines and cells are points. Tic-tac-toe's incidence structure consists of nine points, three horizontal lines, three vertical lines, and two diagonal lines, with each line consisting of at least three points.

History

Games played on three-in-a-row boards can be traced back to ancient Egypt,[6] where such game boards have been found on roofing tiles dating from around 1300 BC.[7]

An early variation of tic-tac-toe was played in the Roman Empire, around the first century BC. It was called terni lapilli (three pebbles at a time) and instead of having any number of pieces, each player had only three; thus, they had to move them around to empty spaces to keep playing.[8] The game's grid markings have been found chalked all over Rome. Another closely related ancient game is three men's morris which is also played on a simple grid and requires three pieces in a row to finish,[9] and Picaria, a game of the Puebloans.

The different names of the game are more recent. The first print reference to "noughts and crosses" (nought being an alternative word for 'zero'), the British name, appeared in 1858, in an issue of Notes and Queries.[10] The first print reference to a game called "tick-tack-toe" occurred in 1884, but referred to "a children's game played on a slate, consisting of trying with the eyes shut to bring the pencil down on one of the numbers of a set, the number hit being scored". "Tic-tac-toe" may also derive from "tick-tack", the name of an old version of backgammon first described in 1558. The US renaming of "noughts and crosses" to "tic-tac-toe" occurred in the 20th century.[11]

In 1952, OXO (or Noughts and Crosses), developed by British computer scientist Sandy Douglas for the EDSAC computer at the University of Cambridge, became one of the first known video games.[12] [13] The computer player could play perfect games of tic-tac-toe against a human opponent.

In 1975, tic-tac-toe was also used by MIT students to demonstrate the computational power of Tinkertoy elements. The Tinkertoy computer, made out of (almost) only Tinkertoys, is able to play tic-tac-toe perfectly.[14] It is currently on display at the Computer History Museum.[15]

Combinatorics

When considering only the state of the board, and after taking into account board symmetries (i.e. rotations and reflections), there are only 138 terminal board positions. A combinatorics study of the game shows that when "X" makes the first move every time, the game outcomes are as follows:[16]

Strategy

A player can play a perfect game of tic-tac-toe (to win or at least draw) if, each time it is their turn to play, they choose the first available move from the following list, as used in Newell and Simon's 1972 tic-tac-toe program.[18]

  1. Win: If the player has two in a row, they can place a third to get three in a row.
  2. Block: If the opponent has two in a row, the player must play the third themselves to block the opponent.
  3. Fork: Cause a scenario where the player has two ways to win (two non-blocked lines of 2).
  4. Blocking an opponent's fork: If there is only one possible fork for the opponent, the player should block it. Otherwise, the player should block all forks in any way that simultaneously allows them to make two in a row. Otherwise, the player should make a two in a row to force the opponent into defending, as long as it does not result in them producing a fork. For example, if "X" has two opposite corners and "O" has the center, "O" must not play a corner move to win. (Playing a corner move in this scenario produces a fork for "X" to win.)
  5. Center: A player marks the center. (If it is the first move of the game, playing a corner move gives the second player more opportunities to make a mistake and may therefore be the better choice; however, it makes no difference between perfect players.)
  6. Opposite corner: If the opponent is in the corner, the player plays the opposite corner.
  7. Empty corner: The player plays in a corner square.
  8. Empty side: The player plays in a middle square on any of the four sides.

The first player, who shall be designated "X", has three possible strategically distinct positions to mark during the first turn. Superficially, it might seem that there are nine possible positions, corresponding to the nine squares in the grid. However, by rotating the board, we will find that, in the first turn, every corner mark is strategically equivalent to every other corner mark. The same is true of every edge (side middle) mark. From a strategic point of view, there are therefore only three possible first marks: corner, edge, or center. Player X can win or force a draw from any of these starting marks; however, playing the corner gives the opponent the smallest choice of squares which must be played to avoid losing.[19] This might suggest that the corner is the best opening move for X, however another study[20] shows that if the players are not perfect, an opening move in the center is best for X.

The second player, who shall be designated "O", must respond to X's opening mark in such a way as to avoid the forced win. Player O must always respond to a corner opening with a center mark, and to a center opening with a corner mark. An edge opening must be answered either with a center mark, a corner mark next to the X, or an edge mark opposite the X. Any other responses will allow X to force the win. Once the opening is completed, O's task is to follow the above list of priorities in order to force the draw, or else to gain a win if X makes a weak play.

More detailed, to guarantee a draw, O should adopt the following strategies:

When X plays corner first, and O is not a perfect player, the following may happen:

Further details

Consider a board with the nine positions numbered as follows:

123
456
789

When X plays 1 as their opening move, then O should take 5. Then X takes 9 (in this situation, O should not take 3 or 7, O should take 2, 4, 6 or 8):

or 6 (in this situation, O should not take 4 or 7, O should take 2, 3, 8 or 9. In fact, taking 9 is the best move, since a non-perfect player X may take 4, then O can take 7 to win).

In both of these situations (X takes 9 or 6 as the second move), X has a property to win.

If X is not a perfect player, X may take 2 or 3 as a second move. Then this game will be a draw, X cannot win.

If X plays 1 opening move, and O is not a perfect player, the following may happen:

Although O takes the only good position (5) as the first move, O takes a bad position as the second move:

Although O takes good positions in the first two moves, O takes a bad position in the third move:

O takes a bad position as first move (except of 5, all other positions are bad):

Variations

See main article: Tic-tac-toe variants. Many board games share the element of trying to be the first to get n-in-a-row, including three men's morris, nine men's morris, pente, gomoku, Qubic, Connect Four, Quarto, Gobblet, Order and Chaos, Toss Across, and Mojo. Tic-tac-toe is an instance of an m,n,k-game, where two players alternate taking turns on an m×n board until one of them gets k in a row. Harary's generalized tic-tac-toe is an even broader generalization. The game can be generalised even further by playing on an arbitrary hypergraph, where rows are hyperedges and cells are vertices.

Other variations of tic-tac-toe include:

One can play on a board of 4x4 squares, winning in several ways. Winning can include: 4 in a straight line, 4 in a diagonal line, 4 in a diamond, or 4 to make a square.

Another variant, Qubic, is played on a 4×4×4 board; it was solved by Oren Patashnik in 1980 (the first player can force a win).[21] Higher dimensional variations are also possible.

In popular culture

Various game shows have been based on tic-tac-toe and its variants:

See also

External links

Notes and References

  1. Web site: Garcia . Dan . GamesCrafters: Tic-Tac-Toe . June 8, 2021 . gamescrafters.berkeley.edu.
  2. Web site: July 1, 2019 . The History of Tic Tac Toe and Where it is Now . June 8, 2021 . Aurosi . en-US.
  3. Web site: MathRec Solutions (Tic-Tac-Toe). Mathematical Recreations. Steve. Schaefer. 2002. September 18, 2015. June 28, 2013. https://web.archive.org/web/20130628112339/http://www.mathrec.org/old/2002jan/solutions.html. dead.
  4. Web site: Tic-Tac-Toe. W.. Weisstein, Eric. mathworld.wolfram.com. en. May 12, 2017.
  5. Book: Pham. Duc-Nghia. Park. Seong-Bae. PRICAI 2014: Trends in Artificial Intelligence: 13th Pacific Rim International Conference on Artificial Intelligence. November 12, 2014. Springer. 978-3-319-13560-1. 735.
  6. Book: Zaslavsky, Claudia. Claudia Zaslavsky. Tic Tac Toe: And Other Three-In-A Row Games from Ancient Egypt to the Modern Computer. 1982. Crowell. 0-690-04316-3. registration.
  7. Book: Parker, Marla. She Does Math!: Real-life Problems from Women on the Job. 1995. Mathematical Association of America. 978-0-88385-702-1. 153.
  8. Web site: Tic tac toe Ancient Roman 1st century BC . Sweetooth Design Company . December 4, 2016.
  9. Web site: Morris Games. www-cs.canisius.edu. September 5, 2012. March 13, 2013. https://web.archive.org/web/20130313100626/http://www-cs.canisius.edu/~salley/SCA/Games/morris.html. dead.
  10. Page:Notes and Queries – Series 2 – Volume 6.djvu/441 . Notes and Queries . Series 2 . VI . 152 .
  11. [Oxford English Dictionary]
  12. Book: Wolf, Mark J. P. . Encyclopedia of Video Games: The Culture, Technology, and Art of Gaming . August 16, 2012 . . 978-0-313-37936-9 . 3–7.
  13. Web site: Cohen . D.S. . OXO aka Noughts and Crosses . Lifewire . March 12, 2019 . August 29, 2019.
  14. Web site: Tinkertoys and tic-tac-toe . September 27, 2007 . dead . https://web.archive.org/web/20070824200126/http://www.rci.rutgers.edu/~cfs/472_html/Intro/TinkertoyComputer/TinkerToy.html . August 24, 2007 .
  15. Book: Original Tinkertoy Computer . January 5, 1978 .
  16. Book: Bolon, Thomas. How to never lose at Tic-Tac-Toe. 2013. BookCountry. 978-1-4630-0192-6. 7.
  17. Web site: Searching for the cat in tic tac toe. Delinski, Bernie. January 21, 2014. Times Daily. timesdaily.com.
  18. Flexible Strategy Use in Young Children's Tic-Tac-Toe. Kevin Crowley, Robert S. Siegler. Cognitive Science. 17. 531–561. 1993. 4 . 10.1207/s15516709cog1704_3 . free .
  19. Book: Gardner, Martin. Hexaflexagons and Other Mathematical Diversions. 1988. University of Chicago Press. 978-0-226-28254-1.
  20. Web site: Kutschera . Ant . The best opening move in a game of tic-tac-toe . The Kitchen in the Zoo . April 7, 2018 . August 29, 2019.
  21. Patashnik. Oren. September 1, 1980. Qubic: 4 × 4 × 4 Tic-Tac-Toe. Mathematics Magazine. 53. 4. 202–216. 10.2307/2689613. 0025-570X. 2689613.
  22. Book: Averbach. Bonnie. Bonnie Averbach. Chein. Orin. Problem Solving Through Recreational Mathematics. Problem Solving Through Recreational Mathematics. 252. 2000. Dover Publications. 978-0-486-40917-7.
  23. Solomon W. . Hypercube tic-tac-toe . Cambridge Univ. Press . Alfred W. . More Games of No Chance (Berkeley, CA, 2000) . Golomb . Hales . 1973012 . Math. Sci. Res. Inst. Publ. . 2002 . 42 . 167–182 . https://web.archive.org/web/20110206014531/http://library.msri.org/books/Book42/files/golomb.pdf . February 6, 2011 . live .
  24. Book: Mendelson, Elliott. Introducing Game Theory and its Applications. 2016. CRC Press. 978-1-4822-8587-1. 19.
  25. Web site: Wild Tic-Tac-Toe . Puzzles in Education . December 11, 2007 . August 29, 2019.
  26. Book: Epstein, Richard A.. The Theory of Gambling and Statistical Logic. December 28, 2012. Academic Press. 978-0-12-397870-7. 450.
  27. Book: Juul, Jesper. Half-Real: Video Games Between Real Rules and Fictional Worlds. 2011. MIT Press. 978-0-262-51651-8. 51.
  28. Michon. John A.. January 1, 1967. The Game of JAM: An Isomorph of Tic-Tac-Toe. 1420555. The American Journal of Psychology. 80. 1. 137–140. 10.2307/1420555. 6036351.
  29. Web site: TicTacToe Magic. December 17, 2016. https://web.archive.org/web/20161220110529/https://people.sc.fsu.edu/~jburkardt/m_src/exm_pdf/tictactoe.pdf. December 20, 2016. dead.
  30. Web site: Tic-Tac-Toe as a Magic Square . Oh Boy! I Get to do Math! . May 30, 2015 . August 29, 2019.
  31. Book: Schumer, Peter D.. Mathematical Journeys. 2004. John Wiley & Sons. 978-0-471-22066-4. 71–72.
  32. Web site: Check Lines . BoardGameGeek . August 29, 2019.
  33. https://videogamegeek.com/videogame/368786/twice-crosses-circles Twice crosses-circles
  34. Goff. Allan. November 2006. Quantum tic-tac-toe: A teaching metaphor for superposition in quantum mechanics. American Journal of Physics. College Park, MD. American Association of Physics Teachers. 74. 11. 962–973. 10.1119/1.2213635. 0002-9505. 2006AmJPh..74..962G.
  35. Web site: Tit, tat, toe. August 29, 2019. The Library of Congress.
  36. Web site: 452: Poultry Slam 2011. This American Life. May 28, 2016. December 2, 2011.
  37. The Chicken Vanishes. Trillin. Calvin. February 1, 1999. The New Yorker. August 29, 2019. 0028-792X.
  38. Web site: Why did the chicken win the game? Conditioning. August 28, 2018. Star Tribune. September 15, 2019.