# How to redefine a function in Mathematica by appending to it?

When doing calculations in Mathematica I often need to redefine a function by appending to it. For example if I define

``````f[n_] := n^2 + n + 1
``````

then after some time I'd like to add 2n^3 so from now on

``````f[n] = 2n^3 + n^2 + n + 1.
``````

Then I'd like to add Sin[n] and going further

``````f[n] = 2n^3 + n^2 + n + 1 + Sin[n].
``````

And so on.

It's easy to do with variables, for example x += 2. Is there something similar for functions?…

Edited to add – yes, I was doing that to semi-manually find a function that fits data the best. I know there are functions to do that but I wanted to see if I can get there myself. I did that but the way was not elegant so that prompted this question.

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It would really help to know what the criterion is that causes you to want to add a term. Is it that different definitions apply for different values of `n`? –  Verbeia Oct 4 '11 at 5:48
@Verbeia It looks like the OP just tries to select a combination of base functions which is appropriate for fitting some experimental data within experimental errors. Probably it is a homework. –  Alexey Popkov Oct 4 '11 at 6:46
@AlexeyPopkov - true, but why mix up polynominal and trigonometric basis functions? I am a simple economist but it just looks odd to me. –  Verbeia Oct 4 '11 at 6:48
@Verbeia If it is known that experimental data contain (or may contain) both periodical and non-periodical components, it is quite logical to use a combination of polynomial and trigonometric function for fitting. –  Alexey Popkov Oct 4 '11 at 7:52
@Alexey just in case you are still doing that by hand :) creativemachines.cornell.edu/eureqa –  belisarius Oct 4 '11 at 12:13

You can define a list of your basis functions and then just pick up needed number of elements:

``````fList = {n^2, n, 1, 2 n^3, Sin[n]};

f[n_] = Total[Take[fList, 3]]
f[n_] = Total[Take[fList, 4]]
f[n_] = Total[Take[fList, 5]]
(*
=> 1 + n + n^2
=> 1 + n + n^2 + 2 n^3
=> 1 + n + n^2 + 2 n^3 + Sin[n]
*)
``````
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I think this works best for my needs, as I can append to the list if needed. Thanks! –  Dunda Oct 4 '11 at 10:14

A late-to-the-party solution: the code below uses an auxiliary function, and to add a term for all subsequent uses, you just have to call a function once, with a second parameter being a pure function expressing the term you want to add:

``````ClearAll[f];
Module[{g},
g[n_] := n^2 + n + 1;
f[n_, add_: Automatic] /; add === Automatic := g[n];
f[n_, add_: Automatic] := Block[{m}, g[m] = g[m] + add[m]; g[n]];
]
``````

Examples of use:

``````In[43]:= f[m]
Out[43]= 1 + m + m^2

In[44]:= f[m, 2 #^3 &]
Out[44]= 1 + m + m^2 + 2 m^3

In[45]:= f[m]
Out[45]= 1 + m + m^2 + 2 m^3

In[46]:= f[m, Sin]
Out[46]= 1 + m + m^2 + 2 m^3 + Sin[m]

In[47]:= f[m]
Out[47]= 1 + m + m^2 + 2 m^3 + Sin[m]
``````

With this approach, you should be careful though to call the two-argument form only once, when you want to add the term to the function - or it will be added every time you call.

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+1, I'm not surprised that you came up with a simple, clever solution for this. –  rcollyer Oct 4 '11 at 12:39
@rcollyer Took me a while. Actually, IMO this one is more a design problem. Thanks for the upvote. –  Leonid Shifrin Oct 4 '11 at 13:07

There are many subtleties craving under your question. Monster subtleties, I mean.

I'll not enter the meander, but you may do something like:

``````f[n] = n^2;
f[n] = f[n] + 2
(* but for evaluation *)
f[n] /. n -> 2
``````

So, for example for plotting this:

``````Plot[f[n] /. n -> x, {x, 0, 1}, AxesOrigin -> {0, 0},
PlotLabel  -> Framed@f[n]]
``````

However, you should NOT do this. Read more about delayed definition!

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It really depends why you need to redefine your function `f`. If the reason is that you realised the previous definition was wrong, then by all means just go back to the cell in question, edit it and re-evaluate it to re-define `f`.

``````f[n_] := n^2 + n + 1
``````

Becomes

``````f[n_] := 2n^3 + n^2 + n + 1
``````

Note the `:=` syntax and the underscore.

If, instead, you want `f` to take the first definition for, say `n<=100` and the second for `n>100`, you would use the Condition syntax `/;`, as shown below.

``````f[n_] := n^2 + n + 1 /; n<=100
f[n_] := 2n^3 + n^2 + n + 1 /; n>100
``````
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This works, but requires separate functions. Generalising the append function is not so easy.

``````Clear[f]
AppendToFunction := (
a = DownValues[f];
b = Append[a[[1, 2]], 2 n^3];
f[n_] = Evaluate[b]);

AppendSinToFunction := (
a = DownValues[f];
b = Append[a[[1, 2]], Sin[n]];
f[n_] = Evaluate[b]);

f[n_] := n^2 + n + 1;
f[3] == 9 + 4
DownValues[f]

(*
->True
->{HoldPattern[f[n_]]:>n^2+n+1}
*)

AppendToFunction
f[3] == 9 + 4 + 54
DownValues[f]

(*
->1+n+n^2+2 n^3
->True
->{HoldPattern[f[n_]]:>1+n+n^2+2 n^3}
*)

AppendSinToFunction
f[3] == 9 + 4 + 54 + Sin[3]
DownValues[f]

(*
->1+n+n^2+2 n^3+Sin[n]
->True
->{HoldPattern[f[n_]]:>1+n+n^2+2 n^3+Sin[n]}
*)
``````
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