I am a senior C/C++/Java/Assembler programmer and I have been always fascinated by the pure functional programming paradigm. From time to time, I try to implement something useful with it, e.g., a small tool, but often I quickly reach a point where I realize that I (and my tool, too) would be much faster in a non-pure language. It's probably because I have much more experience with imperative programming languages with thousands of idoms, patterns and typical solution approaches in my head.
Here is one of those situations. I have encountered it several times and I hope you guys can help me.
Let's assume I write a tool to simulate communication networks. One important task is the generation of network packets. The generation is quite complex, consisting of dozens of functions and configuration parameters, but at the end there is one master function and because I find it useful I always write down the signature:
generatePackets :: Configuration -> [Packet]
However, after a while I notice that it would be great if the packet generation would have some kind of random behavior deep down in one of the many sub-functions of the generation process. Since I need a random number generator for that (and I also need it at some other places in the code), this means to manually change dozens of signatures to something like
f :: Configuration -> RNGState [Packet]
with
type RNGState = State StdGen
I understand the "mathematical" necessity (no states) behind this. My question is on a higher (?) level: How would an experienced Haskell programmer have approached this situation? What kind of design pattern or work flow would have avoided the extra work later?
I have never worked with an experienced Haskell programmer. Maybe you will tell me that you never write signatures because you have to change them too often afterwards, or that you give all your functions a state monad, "just in case" :)