# Are there any value-level logical quantifers in Haskell?

I was working on an abstract algebra library for Python, when I realized that a lot of the dirty work was just constructing loops to correspond to logical expressions with quantifiers. I then realized, while it might be hard to implement a function for logical quantification in Python, it would be easier in Haskell or another language.

Right now I have quantifiers that work as long as the property only involves one variable that is being quantified over, and only if the relation you are quantifying over has three variables, getting over these barriers seems to be the difficult part.

For example, the statement `∀x ∃y (x < y)` causes problems, but `∀x (x = 2) ∃y (y < 3)` is fine.

Are there any existing Haskell libraries that implement value-level logical quantifiers like this? It's difficult to search, because whenever I search something along the lines of "logical quantifiers Haskell" I get lots of things about type quantifiers, which isn't what I want.

The only thing I could find is a `forAll` in Test.QuickCheck, and this does not come with an "exists".

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Interesting. Could you add a little detail about what you want to do with these constructions? I'm unclear whether you want to prove them, manipulate them, assert them, test them or some other thing. –  AndrewC Aug 16 at 14:26
what are you trying to do exactly? Do you want to loop over a certain value range and search for examples or check all values? (like Foldables all and any: hackage.haskell.org/package/base-4.7.0.1/docs/…)? –  Carsten König Aug 16 at 14:28
Ultimately it should produce a Boolean value, and short-curcuit evaluation would be ideal. It should also be able to chain universal and existential operators so they work like they do mathematically, I don't know if `all` and `any` work like that. All and any work with unary predicates, but I want to be able to specify two separate variables for an `all` and `any`, then chain them together to produce a function that takes a binary predicate, and in general chain n different quantifier functions to produce one that takes an n-ary predicate. –  Sintrastes Aug 16 at 14:44
This is what my code looks like now, it works with relations with three variables, and uses an `Int` argument to represent which variable is being quantified over. What I can't do is compose quantifiers to allow n-ary predicates like `(forAll x) .* (exists y) (x < y)`, imagining `.*` to be an operator that composes two quantifiers with variable specified of arites n and m, and produces a quantifier that takes a predicate function of arity n+m. gist.github.com/Sintrastes/… –  Sintrastes Aug 16 at 14:50
What are the domains you are quantifying over? If you have your values in a list then `all` and `any` will work fine (nested as well). –  augustss Aug 16 at 17:50