Talk:Hostage chess
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Move discussion in progress
editThere is a move discussion in progress on Talk:Three-Man Chess which affects this page. Please participate on that page and not in this talk page section. Thank you. —RMCD bot 05:32, 28 October 2019 (UTC)
Excised passage
editThe following passage is so vacuous I can only regard the grandiose philosophy as unwarranted puff.
The variant's inventor, John Leslie, is also a philosopher. He mentions in his book Infinite Minds that the prevalence of chess variant inventions such as hostage chess has led to speculation that there could be infinite possible variations of chess. He contends these will necessarily exceed the capacity of the human mind.[1]
References
- ^ Leslie, John (2003). Infinite Minds: A Philosophical Cosmology (2003 ed.). Clarendon Press. p. 35. ISBN 0199248931.
This is computer science 101. The set of all possible games is determined by the set of all possible rules, and so long as you don't run out of space to jot these down, that's an unbounded set (hence infinite).
But that's not even interesting, because the central nature of chess is the exploration of complex interactions derived from a relatively simple rule set, with a fairly uniform spacial logic underneath (e.g. most of the piece movements are highly symmetric, most are connected, and most can be blocked in geometric ways).
Even there, given just a few hundred binary knobs, you end up with a largish set of chess variants, most of which can be inscribed on a single sheet of paper—but already the size of the set exceeds 2^200, which is particles in universe territory. All combinatorial processes are like this. It's what 'exponential' actually means, when exponential refers to exponential (by far in the minority of casual usage).
The problem is not space, but time. Life is too short to study opening theory for 2^200 different chess variants.
From string theory landscape:
In string theory the number of flux vacua is commonly thought to be roughly , but could be or higher. The large number of possibilities arises from choices of Calabi–Yau manifolds and choices of generalized magnetic fluxes over various homology cycles, found in F-theory.
Hey, once you find the fountain, you could work through 2^200 opening theories for chess-like games before breakfast, and then after lunch you could crunch through the 10^500 different vacua landscapes, to see whether any of these mathematical descriptions matches our own universe in an interesting way.
With numbers like these, who needs a real infinity? This philosophy is so completely unwarranted. — MaxEnt 01:13, 11 August 2022 (UTC)
Section "Example game"
editI just wanted to note that the section "Example game" is of limited usefulness for people like me that can't easily visualize the moves in their head just based on the notations (which is probably the case for the majority of readers). Alenoach (talk) 22:12, 11 August 2024 (UTC)