Suppose I have a bunch of components labeled A-Z... I start by sending each component a value of 1.0 and each component returns a double (say a_0,b_0,..,z_0). Next iteration I send the sum (1.0 + a_0 + ... + z_0) to each component to get 26 new doubles (a_1,...,z_1) and a new value of (1.0 + a_0 + ... +z_0 + ... + a_1 + ... + z_1). The calculation continues in this manner day to day.
The problem is each component is in itself recursive and relies on 20 or so values from previous days. So the most obvious recursive implementation gets messy since each independent path of the component calculation has a massive redundant recursive call.
In my current implementation I separated the components into multiple agents who are responsible for their own state and use message passing to complete the calculation. I'm now in a position where I need to make a change to my model and I'm finding this implementation isn't flexible.
My new idea is to use an immutable object to hold the state of the component where each iteration I'd clone my component object and update the state using a discriminate union. i.e.
Component(oldcomponent, [Parameter1(22.0), Parameter14(10.0)])
would have the state of oldcomponent but update parameters 1 and 14. So that each path of the component calculation would be easy to read since most paths only update a few parameters. And as a bonus I can separate the calculation into a series of functions that that take a list of mutations as input and outputs a new list of mutations.
However, I feel this problem is well suited for a functional language and I'm somewhat deviating from a functional design, which is fine but I'm curious as to how others would go about solving this problem?
I suppose the discriminate union aspect is pointless when I could use a record with the "with syntax" to pass it around.