# how to simplify / expand / apply a pattern to a function's argument

very often I want to simplify the function's argument, or apply a pattern to it, eg. I want to change:

``````Exp[a(b+c)]
``````

into

``````Exp[a b + a c]
``````

simple pattern doesn't help:

``````Sin[a(b+c)] /. Sin[aaa_] -> Sin[Expand[aaa]]
``````

gives again

``````Sin[a(b+c)]
``````

However, with functions other than Simplify / Expand it seems to do what I expect:

``````Sin[a (b + c)] /. Sin[aaa_] -> Sin[f[aaa]]
``````

gives

``````Sin[  f[a(b+c)]  ]
``````

My usual solution was to use 2 patterns and Hold:

``````(Exp[a(b+c)] /. Exp[aaa_] -> Exp[Hold[  Expand[aaa]  ]] ) /. Hold[xxx_] -> xxx
``````

which results in

``````E^(a*b + a*c)
``````

The disadvantage of this method is that code gets more complicated than it's neccesary.

MY REAL LIFE EXAMPLE is:

``````ppp2 =
( ppp1
/. { ExpIntegralEi[aaa_] ->
ExpIntegralEi[Hold[aaa /. { u2 -> 0, w2 -> 0, u3 -> x, w3 -> x}]],
Log[aaa_] ->
Log[Hold[aaa /. {u2 -> 0, w2 -> 0, u3 -> x, w3 -> x}]]
}
) /.  Hold[xxx_] -> xxx;
``````

where ppp1 is a long sum of terms containing u2, w2, u3, w3 and so on. I want to change the values of u, w2... ONLY in ExpIntegral and Log.

My other solution is a function:

``````ExpandArgument[expr_, what_] := Module[{list},
list = Extract[expr, Position[   expr, what[_]   ]];
list = Map[Rule[#, what[Expand[   #[]   ]]] &, list];
Return[expr /. list]
]
``````

The function I wrote can be easily generalised to make it possible to use not only Expand but also Simplify and so on:

``````ApplyToArgument[expr_, ToWhat_, WhatFunction_] := Module[{list},
list = Extract[expr, Position[   expr, ToWhat[_]   ]];
list = Map[Rule[#, ToWhat[WhatFunction[   #[]   ]]] &, list];
Return[expr /. list]
]
``````

For example:

``````ApplyToArgument[Sin[a (b + c)], Sin, Expand]
``````

gives

``````Sin[a b + a c]
``````

and

``````ApplyToArgument[Sin[a b + a c ], Sin, Simplify]
``````

gives

``````Sin[a (b + c)]
``````

This solution is easy to read but needs some refinement before being applied to many-argument functions (and I need these functions).

I guess I'm missing something fundamental about patterns in mathematica... How should I apply patterns to arguments of functions? (Or simplify, expand, etc. them)

Thanks a lot!

• You could use `Map` (or `/@` for short) to apply a function to the arguments of another function. So for your example you could do `Expand /@ Sin[a (b + c)]` which returns `Sin[a b + a c]`. If you only want to apply the function to say the first argument, you could use `MapAt`, e.g. `MapAt[Expand, g[a (b + c), d (e + f)], 1]` – Heike Nov 9 '11 at 11:46
• @Heike Thanks a lot for the comment. I've changed my question to explain that I dont work with single functions, but with long sums of different functions and I want to change arguments of only one type of them. – au700 Nov 9 '11 at 12:04
• This question appears to be off-topic because it is about Mathematica and it should be moved to mathematica.stackexchange.com – Saullo G. P. Castro Oct 16 '13 at 10:50

For the first part of the question, you could consider using `RuleDelayed`:

``````Sin[a (b + c)] /. Sin[aaa_] :> Sin[Expand[aaa]]
``````

gives

``````Sin[a b + a c]
``````
• That is the thing I was looking for. Thanks a lot! – au700 Nov 9 '11 at 13:19
• I didn't mark this answer as an accepted one because I somehow didn't know how to do it. This answer was REALLY helpful, I use it a lot! – au700 Nov 5 '12 at 22:29

Use `:>` instead of `->`. With `->`, the right hand side is immediately evaluated, and only then applied. Expansion of `aaa` of course gives just `aaa`, and therefore evaluation of `Sin[Expand[aaa]]` gives `Sin[aaa]`, thus the rule asks for replacing each application of `Sin` by itself. Then you also should not need those Hold constructs.

In a related note: Instead of applying the rule `Hold[xxx_]->xxx`, you can just pass your expression to `ReleaseHold`, for example `ReleaseHold[Hold[1+1] /. 1->2]` gives 4.

• Thanks a lot! I see the point. Thanks for suggesting ReleaseHold (and providing a nice example). – au700 Nov 9 '11 at 13:23

Also consider using ExpandAll:

``````ExpandAll[Exp[a (b + c)]] // FullForm
``````

will give:

``````Power[E, Plus[Times[a, b], Times[a, c]]]
``````

(This will turn Exp[...] into E^... though)

This is not a direct answer (others provided that), but for these kinds of manipulations the Algebraic Manipulation Palette (Palettes -> Other) is often quite convenient: The disadvantage is that unlike typed-in commands, this operation won't be "recorded" and saved in the notebook.