I'm currently working on a small project (< 10k loc) which is mainly pure but relies on mutable optimizations mainly based on iterators and some data-structure reuse for heavy-duty calculations.

I'd like to learn a bit more functional programming and want to get more type safety, by e.g. wrapping mutable computations into state transformer monads and the like. For this purpose there exists the scalaz library.

### Question One

When abstracting my computations on a larger scale by using all the fancy functional stuff, will I introduce performance killers that I won't get rid of? Like when my calculation is wrapped deep to the knees in Monads?

### Question Two

Is it feasibly at all considering Scala's limited type inference? I'm currently fighting with very large type signatures (maybe because I don't know how to properly get rid of them). I suppose that going more "functional" will introduce even more such boiler-plate code.

### Disclaimer

I'm not questioning whether the functional approach is good or bad. Asking this question for Haskell is pointless. I am questioning whether it is sensible doing so for Scala.

### Edit on request: example of large type signatures in my project

*(but this would be a different question)*

The following code describes an iterative computation on a type-parameterized input object (`DiscreteFactorGraph[VariableType, FactorType[VariableType]]`

). You can construct a computation object with `createInitialState`

and perform computation on it with `advanceState`

and finally extract some information from it with `marginals`

.

I want the type of the factor graph object (and its parameter types) to be preserved during the computation so that the final application of `marginals`

yields the correct type of `DiscreteMarginals[VariableType]`

. I think currently I only have to preserve the variable type inside the computation type (which is `TState`

), so carrying around the factor type is not used. But at a different place I need even the type of `DiscreteFactorGraph`

to be variable, so I tend to need more type information carried through the computation in the future.

I was fiddlying around with this part a lot and I hope there's some better solution. Currently I have a pretty functional approach, where there are only those three functions. But I have to chain the type through them. Alternatively I can define it as a class and parameterise the class with all those types, so I don't have to repeat the type parameters for each method.

```
object FloodingBeliefPropagationStepper extends SteppingGraphInferer {
def marginals[V <: DiscreteVariable, F <: DiscreteFactor[V]](state: FloodingBeliefPropagationStepper.TState[V,F]): DiscreteMarginals[V] =
BeliefPropagation.marginals(state._1, state._2)
def advanceState[V <: DiscreteVariable, F <: DiscreteFactor[V]](state: FloodingBeliefPropagationStepper.TState[V,F]): FloodingBeliefPropagationStepper.TState[V,F] = {
val graph = state._1
(graph,
BeliefPropagation.computeFactorMessages(
graph,
BeliefPropagation.computeVariableMessages(graph, state._2, graph.variables),
graph.factors))
}
def createInitialState[V <: DiscreteVariable, F <: DiscreteFactor[V]](graph: DiscreteFactorGraph[V, F],
query: Set[V],
random: Random): FloodingBeliefPropagationStepper.TState[V,F] = {
(graph,
BeliefPropagation.computeFactorMessages(
graph,
BeliefPropagation.createInitialVariableMessages(graph, random),
graph.factors))
}
type TState[V <: DiscreteVariable, F <: DiscreteFactor[V]] = (DiscreteFactorGraph[V,F],Map[(F,V),DiscreteMessage])
}
```

`FloodingBeliefPropagationStepper.TState`

. And if you're after a high-performance solution, using`DiscreteVariable`

instead of`Int`

or somesuch is likely to cause the largest performance hit (unless you actually need to do very little with the variables). So far, the code looks like it's written to maximize abstraction not performance. So how worried should you really be about performance? – Rex Kerr Aug 17 '11 at 15:55`DiscreteVariable`

is only a description of the variable itself and does not hold any state (the concrete data structures for holding the state of a computation are created at a lower level from the "problem specification" that is described by the graph). And indeed you're looking at an abstraction class and the computations are at a lower level, like in`BeliefPropagation`

. – ziggystar Aug 17 '11 at 16:43