# Mathematica Map question

Original question:

I know Mathematica has a built in map(f, x), but what does this function look like? I know you need to look at every element in the list.

Any help or suggestions?

Edit (by Jefromi, pieced together from Mike's comments):

I am working on a program what needs to move through a list like the Map, but I am not allowed to use it. I'm not allowed to use Table either; I need to move through the list without help of another function. I'm working on a recursive version, I have an empty list one down, but moving through a list with items in it is not working out. Here is my first case: `newMap[#, {}] = {}` (the map of an empty list is just an empty list)

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What do you mean by "what does this function look like"? I assume you're asking about `Map`; have you looked at the documentation? Is there something there that confuses you? – Jefromi Nov 8 '10 at 18:43
I'm not sure what your looking for. Are you looking for the signature of `Map` (argument layout), how it operates, or how it's implemented? – rcollyer Nov 8 '10 at 18:45
I'm looking for how it operates, how to recursively move through a list in mathematica, and especially what is the first argument in Map, how to implement if I was written that myself I know Map(__, List) what would I put in the first bracket? – Mike Nov 8 '10 at 18:51
@Mike: You can't possibly do it without using any functions; everything's a function, even `First`, `Last`, and `Part`. If you could edit your question to state exactly what it is you need to do and what your restrictions are, we can provide helpful answers, instead of trying to guess. Also, if your comment refers to an answer, you can comment on the answer itself, rather than your question. – Jefromi Nov 8 '10 at 19:07

I posted a recursive solution but then decided to delete it, since from the comments this sounds like a homework problem, and I'm normally a teach-to-fish person.

You're on the way to a recursive solution with your definition `newMap[f_, {}] := {}`.

Mathematica's pattern-matching is your friend. Consider how you might implement the definition for `newMap[f_, {e_}]`, and from there, `newMap[f_, {e_, rest___}]`.

One last hint: once you can define that last function, you don't actually need the case for `{e_}`.

UPDATE:

``````func[a_, b_] := a[b]

In[4]:= func[Abs, x]
Out[4]= Abs[x]
``````

SOLUTION

Since the OP caught a fish, so to speak, (congrats!) here are two recursive solutions, to satisfy the curiosity of any onlookers. This first one is probably what I would consider "idiomatic" Mathematica:

``````map1[f_, {}] := {}
map1[f_, {e_, rest___}] := {f[e], Sequence@@map1[f,{rest}]}
``````

Here is the approach that does not leverage pattern matching quite as much, which is basically what the OP ended up with:

``````map2[f_, {}] := {}
map2[f_, lis_] :=  {f[First[lis]], Sequence@@map2[f, Rest[lis]]}
``````

The `{f[e], Sequence@@map[f,{rest}]}` part can be expressed in a variety of equivalent ways, for example:

• `Prepend[map[f, {rest}], f[e]]`
• `Join[{f[e]}, map[f, {rest}]` (@Mike used this method)
• `Flatten[{{f[e]}, map[f, {rest}]}, 1]`

I'll leave it to the reader to think of any more, and to ponder the performance implications of most of those =)

Finally, for fun, here's a procedural version, even though writing it made me a little nauseous: ;-)

``````map3[f_, lis_] :=
(* copy lis since it is read-only *)
Module[{ret = lis, i},
For[i = 1, i <= Length[lis], i++,
ret[[i]] = f[lis[[i]]]
];
ret
]
``````
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`_` is `Blank`, and matches any expression. `f_` effectively just assigns whatever was matched to a local variable `f` in the function definition. It might be helpful to read the "Introduction to Patterns" tutorial. – Michael Pilat Nov 8 '10 at 22:30
The built-in `Map` will map over any head so maybe something more like `newMap[f_, lst_[a_, b__]] := ...` would be more appropriate. There's one last trick that can be used in this method, which is the use of Sequence@@, which can be abbreviated/obfuscated to ##&@@ – Simon Nov 8 '10 at 22:36
`+` does not join lists, it is always an arithmetic operator in Mathematica. Suggested reading: "List Manipulation" – Michael Pilat Nov 8 '10 at 23:05
Some functions in Mathematica are "`Listable`", meaning they automatically map themselves over any list arguments. Compare the results of evaluating `Abs[{1, -1, 2}]` vs. `f[{1, 2, 3}]`. If your solution is correct, `maps[f, {1,2,3}]` will give `{f[1],f[2],f[3]}`, but I believe it will instead output `{f[1], f[{2,3}]}` and probably some errors. – Michael Pilat Nov 8 '10 at 23:36
In your function, `Rest[x]` correctly gives the "rest" of the list, and then you need to map `fun` over it, and join it to the first part. But, you already have a function to map `fun` over a list, so... – Michael Pilat Nov 8 '10 at 23:59

To answer the question you posed in the comments, the first argument in `Map` is a function that accepts a single argument. This can be a pure function, or the name of a function that already only accepts a single argument like

``````In[1]:=f[x_]:= x + 2
Map[f, {1,2,3}]
Out[1]:={3,4,5}
``````

As to how to replace `Map` with a recursive function of your own devising ... Following Jefromi's example, I'm not going to give to much away, as this is homework. But, you'll obviously need some way of operating on a piece of the list while keeping the rest of the list intact for the recursive part of you map function. As he said, `Part` is a good starting place, but I'd look at some of the other functions it references and see if they are more useful, like `First` and `Rest`. Also, I can see where `Flatten` would be useful. Finally, you'll need a way to end the recursion, so learning how to constrain patterns may be useful. Incidentally, this can be done in one or two lines depending on if you create a second definition for your map (the easier way), or not.

Hint: Now that you have your end condition, you need to answer three questions:

1. how do I extract a single element from my list,
2. how do I reference the remaining elements of the list, and
3. how do I put it back together?

It helps to think of a single step in the process, and what do you need to accomplish in that step.

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Given that table is disallowed, First/Rest are definitely nice idioms here. – Jefromi Nov 8 '10 at 20:18