Talk:Counting problem (complexity)

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y, to my understanding, isn't necessarily a number, so what's the meaning of the inequality? I think it's supposed to be y is a subset of the set defined in the cardinality of c_r..

In my understanding the symbol ${\displaystyle y}$ denotes a non-negative integer that can hence be compared to ${\displaystyle c_{R}(x)}$, the size (that is number of elements) of the set of solutions ${\displaystyle \{y\mid (x,y)\in R\}}$. I believe one needs to be a bit more careful in phrasing the definition, because a priori there is no bound on the number of solutions since in general ${\displaystyle R}$ is a binary relation between infinite sets (e.g. all strings over a finite (usually two-element) alphabet). Of course one may allow infinitely many solution for certain inputs ${\displaystyle x}$. For such ${\displaystyle x}$ every pair ${\displaystyle (x,n)}$ will belong to ${\displaystyle \#R}$. One way to make the number ${\displaystyle c_{R}(x)}$ always finite is to just postulate this in the definition of ${\displaystyle R}$. Often this is achieved by making more restrictive assumptions such a that there is a function ${\displaystyle f\colon \mathbb {N} \to \mathbb {N} }$ (of a certain kind, e.g. a polynomial function) such that for every input ${\displaystyle x}$ there are only solutions ${\displaystyle y}$ satisfying ${\displaystyle (x,y)\in R}$ with bounded length ${\displaystyle |y|\leq f(|x|)}$ and hence finitely many.

I think the problem needs to be stated in English, as with this unspecified notation it's basically unintelligible. 81.2.154.16 (talk) 20:30, 7 July 2022 (UTC)[reply]