# Telling Plot to style vector-valued black-box functions in Mathematica

Suppose I write a black-box functions, which evaluates an expensive complex valued function numerically, and then returns real and imaginary part.

``````fun[x_?InexactNumberQ] := Module[{f = Sin[x]}, {Re[f], Im[f]}]
``````

Then I can use it in Plot as usual, but Plot does not recognize that the function returns a pair, and colors both curves the same color. How does one tell Mathematica that the function specified always returns a vector of a fixed length ? Or how does one style this plot ? EDIT: Given attempts attempted at answering the problem, I think that avoiding double reevalution is only possible if styling is performed as a post-processing of the graphics obtained. Most likely the following is not robust, but it seems to work for my example:

``````gr = Plot[fun[x + I], {x, -1, 1}, ImageSize -> 250];
k = 1;
{gr, gr /. {el_Line :> {ColorData[k++], el}}}
`````` • I don't think there's any documented way to do this. – Brett Champion Apr 8 '11 at 17:47
• I tried running a `Trace[Plot[{Sin[x], Cos[x]}, {x, -1, 1}], TraceInternal -> True]` to figure out where Mma determines the number of lines and assigns colors/styles - but it didn't make anything clearer. Maybe someone else will have better luck understanding the output. – Simon Apr 9 '11 at 0:31

One possibility is:

``````Plot[{#[], #[]}, {x, -1, 1}, PlotStyle -> {{Red}, {Blue}}] &@ fun[x + I]
`````` Edit

If your functions are not really smooth (ie. almost linear!), there is not much you can do to prevent the double evaluation process, as it will happen (sort of) anyway due to the nature of the Plot[] mesh exploration algorithm.

For example:

``````fun[x_?InexactNumberQ] := Module[{f = Sin[3  x]}, {Re[f], Im[f]}];
Plot[{#[], #[]}, {x, -1, 1}, Mesh -> All,
PlotStyle -> {{Red}, {Blue}}] &@fun[x + I]
`````` • If one inserts Sow inside fun, and wraps Reap around the plot, it is seen that for some value of x the function is evaluated twice. I do not understand why, though. Let fun[x_?InexactNumberQ] := Module[{f = Sin[x]}, Sow[x]; {Re[f], Im[f]}] Then (Reap[Plot[{#[], #[]}, {x, -1, 1}, PlotStyle -> {{Red}, {Blue}}] &@fun[x + I]][[-1, 1]] // Tally)[[All, 2]] // Tally gives {{2, 78}, {1, 197}}, so there is a room for savings. – Sasha Apr 8 '11 at 16:35
• @Sasha Yep. I missed your "expensive function" statement. You may use memoization, though – Dr. belisarius Apr 8 '11 at 16:42
• This seems to avoid some of the reevals. Pretty cheesy though, unless you go to the trouble of localizing the global variable. fun[x_?InexactNumberQ] := Module[{f = Sin[x]}, Sow[x]; tagalong = Im[f]; Re[f]] g[x_] := tagalong pts = Reap[ Plot[{#[], g[#[]]}, {x, -1, 1}, PlotStyle -> {{Red}, {Blue}}] &@{fun[x + I], tagalong}][[2, 1]]; – Daniel Lichtblau Apr 8 '11 at 18:57
• +1 The point made in your edit is a good one. – Simon Apr 8 '11 at 22:34
• Although not a direct answer to my question, your analysis shows that there is only so much unneeded evaluations I can avoid without overriding automatic subdivision. Accepting. – Sasha Apr 17 '11 at 14:50

I don't think there's a good solution to this if your function is expensive to compute. Plot will only acknowledge that there are several curves to be styled if you either give it an explicit list of functions as argument, or you give it a function that it can evaluate to a list of values.

The reason you might not want to do what @belisarius suggested is that it would compute the function twice (twice as slow).

However, you could use memoization to avoid this (i.e. the f[x_] := f[x] = ... construct), and go with his solution. But this can fill up your memory quickly if you work with real valued functions. To prevent this you may want to try what I wrote about caching only a limited number of values, to avoid filling up the memory: http://szhorvat.net/pelican/memoization-in-mathematica.html

• Caching will be more useful if the Real and Imaginary parts don't have "interesting points". Plot will try to explore those points for each part. I'll update my answer. – Dr. belisarius Apr 8 '11 at 17:42

If possible for your actual application, one way is to allow `fun` to take symbolic input in addition to just numeric, and then `Evaluate` it inside of `Plot`:

``````fun2[x_] := Module[{f = Sin[x]}, {Re[f], Im[f]}]

Plot[Evaluate[fun2[x + I]], {x, -1, 1}]
`````` ``````Plot[{-Im[Sinh[1 - I x]], Re[Sinh[1 - I x]]}, {x, -1, 1}]