It just seemed to me studying GEP,and especially analyzing Karva expressions, that Non Terminals are most suitable for functions which type is `a->a`

for some type `a`

, in Haskell notation.

Like, with classic examples, `Q+-*/`

are all functions from 'some' Double to 'a' Double and they just change in arity.

Now, how can one coder use functions of heterogeneous signature in one Karva expressed gene?

## Brief Introduction to GEP/Karva

**Gene Expression Programming** uses dense representations of a population of expressions and applies evolutionary pressure to make better ones to solve a given problem.

**Karva notation** represents an expression tree as a string, represented in a non-traditional traversal of level-at-a-time, left-to-right - read more here. Using Karva notation, it is simple and quick to combine (or mutate) expressions to create the next generation.

You can parse Karva notation in Haskell as per this answer with explanation of linear time or this answer that's the same code, but with more diagrams and no proof.

**Terminals** are the constants or variables in a Karva expression, so `/+a*-3cb2`

(meaning `(a+(b*2))/(3-c)`

) has terminals [a,b,2,3,c]. A Karva expression with no terminals is thus a function of some arity.

My Question is then more related to how one would use different types of functions without breaking the gene.

What if one wants to use a Non Terminal like a > function? One can count on the fact that, for example, it can compare Doubles. But the result, in a strongly typed Language, would be a Bool. Now, assuming that the Non terminal encoding for > is interspersed in the gene, the parse of the k-expression would result in invalid code, because anything calling it would expect a Double. One can then think of manually and silently sneak in a cast, as is done by Ms. Ferreira in her book, where she converts Bools into Ints like 0 and 1 for False and True.

Si it seems to me that k-expressed genes are for Non Terminals of any arity, that share the property of taking values of one type a, returning a type a.

In the end, has anyone any idea about how to overcome this? I already now that one can use homeotic genes, providing some glue between different Sub Expression Trees, but that, IMHO, is somewhat rigid, because, again, you need to know in advance returned types.

`Q`

has arity 1 (e.g.`q :: Double -> Double`

; the other functions you mention have arity 2 (e.g.`(/) :: Double -> Double -> Double`

). But I can't answer the question, because (only) the sentence that ends in a question mark doesn't make sense to me. Do you mean you want to have terminals with types like`a -> b -> a`

? I don't see how that'd be much of a problem in (typed) K-expressions. – Rhymoid Jun 15 '14 at 15:12