# Defining a function with an optional value that is by default a function of another paramether of the function in mathematica

I am trying to define a function that takes in a Matrix and when its dimensions are not provided as input, compute these dimensions in the optional parameter `d`

This does not work but gives you the idea (The options parameter need be constants):

``````Options[DimM] = {d -> Dimensions[A]};
DimM[A_?MatrixQ, OptionsPattern[]] := OptionValue@d;
``````

Indeed the simple way is to input an impossible value and in the function def put an if condition as in

``````Options[DimM] = {d -> 0};
DimM[A_?MatrixQ, OptionsPattern[]] :=If[OptionValue@d==0,Dimensions[A],OptionValue@d]
``````

How can I accomplish this most efficiently?

## 2 Answers

For your original formulation, @WReach gave a fine answer. However, it may make sense to reconsider your design a bit: note that you have a (dependent on input arguments) value for `d` in any case. Optional arguments are designed exactly for that - to be optional. In your case, a default argument seems more appropriate. You can set it up with `Automatic`, similarly to what @WReach suggested:

``````dimMAuto[a_?MatrixQ, d_: Automatic] :=
If[d === Automatic, Dimensions[a], d];
``````

To use this in more than one place in your code, you will however need to introduce an auxiliary variable or constant (using `With` or `Module`), to store this value. As an alternative, you can also use the following code:

``````Module[{dims},
dimM[a_?MatrixQ, d_: dims] :=
Block[{dims = Dimensions[a]},
d]
]
``````

which has the advantage that you can use the same original parameter `d` everywhere in the body of your function. What happens here is rather non-trivial: `Module` is used to generate a unique symbol, which is then given as a default for `d` and used to dynamically compute the dimensions. Note that `Block` localizes not the symbol `dims`, but the unique symbol like `dims\$77542` produced by `Module`. This combination of `Module` and `Block` makes this technique completely safe. Examples of use:

``````In:= dimM[IdentityMatrix,{1,1}]
Out= {1,1}

In:= dimM[IdentityMatrix]
Out= {3,3}
``````

I think this combination of `Module` and `Block` is an interesting technique which may find other uses. Essentially, it is a version of dynamic scoping made safe by lexical scoping (or, more precisely, its imitation in Mathematica) - since one of the main dangers of dynamic scoping is inadvertent collisions of dynamically localized symbols with the same name.

On an unrelated matter - it is best to not start your variables and functions with a capital letter, since they may collide with the system symbols.

• This is quite deep! my only concern here is efficiency. It seems the Module/Block combination computes Dimensions[a] whether or not a value for d is supplied which is precisely what I am trying not to do. Am I missing something? – Phil Sep 12 '11 at 22:54
• @Phil Yes, you are right. In the case of `Dimensions`, overhead is probably not very significant, but if this is just a toy example for you, I see your point. You may make it compute the function conditionally at the price of making code a bit uglier: `Module[{dims},dimM[a_?MatrixQ, d_: dims] := Block[{dims}, If[d===dims,dims = Dimensions[a]]; function-body]]`. Perhaps, this destroys a purpose a bit, but you still have the advantage of using the original parameter `d` everywhere in the body. You can also write a macro to abstract away the `Module`-`Block` part. – Leonid Shifrin Sep 12 '11 at 23:04
• If I understand this correctly, the use of `Block` within `Module` value is to create a dynamic default via a local, unique var which can acquire its value as needed. Clever. +1. – rcollyer Sep 13 '11 at 3:16
• @rcollyer Yes, that's the idea. Just using `Block[{dims},...` is dangerous because in principle the body of the function may use the same global symbol `dims` for some unrelated purpose, in the chain of function calls resulting from evaluation of the body (with `dims` not necessarily lexically present in the body). This is a major problem with dynamic scoping. But, by using `Module`, we ensure that the dynamically - scoped symbol in question is unique and can not possibly collide with other symbols. AFAICT, this variation of dynamic scoping is much safer. I used it a few times before. – Leonid Shifrin Sep 13 '11 at 8:49
• Yet another interesting dissertation, Leonid. :-) – Mr.Wizard Oct 16 '11 at 17:27

This is not really an improvement over your "simple way", but for many built-in Mathematica functions the symbol `Automatic` is used as the "impossible value". For example:

``````Options[DimM] = {d -> Automatic};
DimM[A_?MatrixQ, OptionsPattern[]] := OptionValue[d] /. Automatic->Dimensions[A]

DimM[RandomInteger[10, {2, 2}]]
(* {2, 2} *)

DimM[RandomInteger[10, {2, 2}], d -> {5, 5}]
(* {5, 5} *)
``````
• thanks. How about if I have more than one optional parameter? how do I name them all? – Phil Sep 12 '11 at 22:01
• You can use `Automatic` for all of them. Then, inside the function you reference each option in turn thus:`a = OptionValue[A] /. Automatic -> defaultA; b = OptionValue[B] /. Automatic -> defaultB`. – WReach Sep 12 '11 at 22:09
• Right, right! Do we still compute Dimensions[A] if a value for d is provided? I think not, since if Automatic is not found in OptionValue[d], then the replacement rule is not activated. Am I missing it? My goal is to avoid computing Dimensions[A] if in the context I already know it and can pass it on. – Phil Sep 12 '11 at 23:00
• @Phil As written, the solution does compute `Dimensions` in any case. To avoid computing `Dimensions` in this approach, you can simply use delayed rules: `Automatic :> defaultA`, etc. – Leonid Shifrin Sep 12 '11 at 23:07
• You are correct that the replacement rule will not be activated if the option value is anything other than `Automatic`. However, as I have written it, `Dimensions[A]` will always be evaluated. To avoid this calculation when unnecessary, the replacement rule would have to be written as a deferred rule, i.e. `Automatic :> Dimensions[A]`. – WReach Sep 12 '11 at 23:10