# Mapping two argument function in Mathematica

I want to archive:

``````Map2[f,{a,b,c,d}]
{f[a,b], f[b,c], f[c,d]}
``````

But for some reason, I can only think of iterative approaches.

What's the functional way?

# Edit:

Use of this, was to generate graph examples. If number list is given, following generates the graph of what it would mean, to sequentially visit all the nodes.

For example:

``````Map2 = # @@@ Partition[#2, 2, 1] &;
MG[elems_] := Graph[Map2[DirectedEdge, elems]]
nrs = RandomInteger[{1, 15}, 20]
MG[nrs]
``````

{10,13,9,7,13,3,5,1,15,10,15,6,14,3,1,2,11,4,8,5}

-
@d00b it must be; `Graph` is not in v7. – Mr.Wizard May 30 '11 at 11:03
@d00b: Yes, this use case is for Mathematica 8. Although note, that question itself is not version specific. All the more reason, to appreciate good answers. – Margus May 30 '11 at 20:33
@Wizard: Thank you. – user564376 May 30 '11 at 21:32

Most simply:

``````Map2 = # @@@ Partition[#2, 2, 1] &;
``````

Or, possibly using less memory, but running a bit slower:

``````Map2[f_, lst_] := Developer`PartitionMap[f @@ # &, lst, 2, 1]
``````

Also, be aware of `Differences` and `Accumulate`, which are related.

Other ways:

``````Inner[#, Most@#2, Rest@#2, List] &
``````

Notice that in this one `List` could be a different function.

``````MapThread[#, {Most@#2, Rest@#2}] &

Table[# @@ #2[[i ;; i + 1]], {i, Length@#2 - 1}] &
``````

Now, the timings. I will make use of Timo's `timeAvg`.

``````f1 = # @@@ Partition[#2, 2, 1] &;
f2[f_, lst_] := Developer`PartitionMap[f @@ # &, lst, 2, 1]
f3 = Inner[#, Most@#2, Rest@#2, List] &;
f4 = MapThread[#, {Most@#2, Rest@#2}] &;
f5 = Most@MapThread[#, {#2, RotateLeft@#2}] &;
f6 = Table[# @@ #2[[i ;; i + 1]], {i, Length@#2 - 1}] &;

timings =
Table[
list = RandomReal[99, 10^i];
func = Plus;
timeAvg[#[func, list]] & /@ {f1, f2, f3, f4, f5, f6},
{i, 6}
];

TableForm[timings,
TableHeadings -> {10^Range@6, {"f1", "f2", "f3", "f4", "f5", "f6"}}]

ListLogPlot[timings\[Transpose], Joined -> True]
``````

The numbers on the left side of the table are the length of the list of real numbers for each run.

Note that the graph is logarithmic.

Here are the bytes of memory used while processing the longest list (1,000,000):

After doing the timings above, I found I can make `f6` faster by eliminating `Apply` (`@@`). It is now clearly the fastest on longer lists. I will not add it to the table above because that is already wide enough, but here is the function and its timings:

``````f7 = Table[#2[[i]] ~#~ #2[[i + 1]], {i, Length@#2 - 1}] &;
``````

-
@Mr.Wizard: Works great. – Margus May 29 '11 at 14:02
@Margus, I am glad that helps. I am not done with my answer. There are other ways, and I want to add timings, so check back later. – Mr.Wizard May 29 '11 at 14:07
@Mr. Wizard: Ok :D – Margus May 29 '11 at 14:10
@Mr. I am going to add all your functions to my answer in retaliation :) – Dr. belisarius May 29 '11 at 14:45
@Mr. I am taking offense of this :). You forgot to include my only contribution in the test. Did I win? :) – Dr. belisarius May 29 '11 at 15:01

As explained in the Mathematica cookbook mapping a function over a moving sublist can be elegantly solved with the ListConvole function:

``````Map2[f_, l_List] := ListConvolve[{1, 1}, l, {-1, 1}, {}, #2 &, f]

In[11]:= Map2[f, {a, b, c, d}]
Out[11]= {f[a, b], f[b, c], f[c, d]}
``````

Mr.Wizard here, adding comparative timings as requested by sakra.

-
I knew I was forgetting something. :-) – Mr.Wizard May 29 '11 at 19:55
(grumble mode) I voted for this myself, because it is helpful, but it is not the best method here. In fact, it is slower than any of the options I gave. Nothing against you sakra, but I don't think it should rank so highly. – Mr.Wizard May 30 '11 at 8:33
@Mr.Wizard Can you add the ListConvole option to your timing test plot? – sakra May 30 '11 at 8:39
@Mr.Wizard, sure! – sakra May 30 '11 at 9:57
sakra, may I edit your post to include a comparative graph, or would you prefer that I do not? – Mr.Wizard May 30 '11 at 10:04

I like:

``````Map2[f_, l_List]:= MapThread[f, {Most@l, Rest@l}]

In[988]:= Map2[f,{a,b,c,d}]
Out[988]= {f[a,b],f[b,c],f[c,d]}
``````
-
This also works. – Margus May 29 '11 at 14:39

I recently re-read your question and saw your `Graph[ ]` application.

I think the natural way to do that is:

``````f[l_] := Graph[Thread[Most@l -> Rest@l]]
``````

So

``````f[{10, 13, 9, 7, 13, 3, 5, 1, 15, 10, 15, 6, 14, 3, 1, 2, 11, 4, 8, 5}]
``````

-
+1 for bothering to read the updated question, and giving a good solution. – Mr.Wizard May 30 '11 at 8:33

Following belisarius' lead, and addressing your `Graph` application, this should be a little faster:

``````f = Inner[Rule, Most@#, Rest@#, Composition[Graph, List]] &;
``````
-
I think that being the current application to display a directed graph, it is doubtful that speed matters that much. A huge Graph is almost illegible :). +1 – Dr. belisarius May 30 '11 at 11:32
@belisarius I thought `Graph` was used for other stuff, not just display. No? Thanks for the +1 anyway. I like your solution much better. – Mr.Wizard May 30 '11 at 12:09
from the question context seems the display is the objective, but you may well be right. – Dr. belisarius May 30 '11 at 12:13

Wow, I saw the other solutions and they seem quite complex and obfuscate. This is a lot simpler to understand, at least if you like a more functional approach:

``````MapApplyImpl[fun_] := Function[{args}, Apply[fun, args]]
MapApply[fun_, argList_] := Map[MapApplyImpl[fun], argList]
``````

and a usage example:

``````ff := Function[{t, phi}, t*phi]
MapApply[ff, {{0, Pi/4}, {(Pi/4)/(10^3) , 0}, {(2*Pi/(10^3)),
Pi/4}}]
``````
-