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I often have a list of pairs, as

data = {{0,0.0},{1,12.4},{2,14.6},{3,25.1}}

and I want to do something, for instance Rescale, to all of the second elements without touching the first elements. The neatest way I know is:

Transpose[MapAt[Rescale, Transpose[data], 2]]

There must be a way to do this without so much Transposeing. My wish is for something like this to work:

MapAt[Rescale, data, {All, 2}]

But my understanding is that MapAt takes Position-style specifications instead of Part-style specifications. What's the proper solution?

To clarify,

I'm seeking a solution where I don't have to repeat myself, so lacking double Transpose or double [[All,2]], because I consider repetition a signal I'm not doing something the easiest way. However, if eliminating the repetition requires the introduction of intermediate variables or a named function or other additional complexity, maybe the transpose/untranspose solution is already correct.

share|improve this question
Note that [[All,2]] has the same number of characters as Transpose. So far the solutions are interesting, but I think none is shorter than the double-transpose one, especially if you permit the esc-tr-esc shortcut. Perhaps I should have posed the question as a code golf challenge? – ArgentoSapiens Dec 20 '11 at 19:15
if you want a shorter solution you probably should specifically ask for it. different people will consider different things to be the (proper OR most elegant OR easiest to understand) solution. – acl Dec 20 '11 at 19:21
Well if you simply don't want a double Transpose or double [[All,2]], both answers I gave seem suitable :) (I'd go for Mr.W's though, it's easier to read if not to write) – acl Dec 20 '11 at 19:34
Why is you data that form on the first place, {{_Integer,_Real},..} performance wise {{__Integer},{__Real}} where better and then you would not have the problem to begin with. – user1054186 Dec 20 '11 at 19:44
Thanks, all, for your answers. There is not always a super-compact way to do these things; these solutions have shown the variety that is possible when seeking a balance between compactness and versatility. – ArgentoSapiens Dec 20 '11 at 21:35
up vote 10 down vote accepted

Use Part:

data = {{0, 0.0}, {1, 12.4}, {2, 14.6}, {3, 25.1}}

data[[All, 2]] = Rescale @ data[[All, 2]];


Create a copy first if you need to. (data2 = data then data2[[All, 2]] etc.)

Amending my answer to keep up with ruebenko's, this can be made into a function also:

partReplace[dat_, func_, spec__] :=
  Module[{a = dat},
    a[[spec]] = func @ a[[spec]];

partReplace[data, Rescale, All, 2]

This is quite general is design.

share|improve this answer
Putting it in your own words, +1 for doing it exactly the way I'd do it (but see my answer below for a few minor differences) – Leonid Shifrin Dec 20 '11 at 20:49

I am coming late to the party, and what I will describe will differ very little with what @Mr. Wizard has, so it is best to consider this answer as a complementary to his solution. My partial excuses are that first, the function below packages things a bit differently and closer to the syntax of MapAt itself, second, it is a bit more general and has an option to use with Listable function, and third, I am reproducing my solution from the past Mathgroup thread for exactly this question, which is more than 2 years old, so I am not plagiarizing :)

So, here is the function:

Options[mapAt] = {MappedListable -> False}; 
mapAt[f_, expr_, {pseq : (All | _Integer) ..}, OptionsPattern[]] := 
  Module[{copy = expr}, 
    copy[[pseq]] = 
      If[TrueQ[OptionValue[MappedListable]] && Head[expr] === List, 
        f /@ copy[[pseq]] 
mapAt[f_, expr_, poslist_List] := MapAt[f, expr, poslist]; 

This is the same idea as what @Mr. Wizard used, with these differences: 1. In case when the spec is not of the prescribed form, regular MapAt will be used automatically 2. Not all functions are Listable. The solution of @Mr.Wizard assumes that either a function is Listable or we want to apply it to the entire list. In the above code, you can specify this by the MappedListable option.

I will also borrow a few examples from my answer in the above-mentioned thread:

In[18]:= mat=ConstantArray[1,{5,3}];

In[19]:= mapAt[#/10&,mat,{All,3}]
Out[19]= {{1,1,1/10},{1,1,1/10},{1,1,1/10},{1,1,1/10},{1,1,1/10}}

In[20]:= mapAt[#/10&,mat,{3,All}]
Out[20]= {{1,1,1},{1,1,1},{1/10,1/10,1/10},{1,1,1},{1,1,1}}

Testing on large lists shows that using Listability improves the performance, although not so dramatically here:

In[28]:= largemat=ConstantArray[1,{150000,15}];

In[29]:= mapAt[#/10&,largemat,{All,3}];//Timing
Out[29]= {0.203,Null}

In[30]:= mapAt[#/10&,largemat,{All,3},MappedListable->True];//Timing
Out[30]= {0.094,Null}

This is likely because for the above function (#/10&), Map (which is used internally in mapAt for the MappedListable->False (default) setting, was able to auto-compile. In the example below, the difference is more substantial:

f[x_] := 2 x - 1;

In[54]:= mapAt[f,largemat,{All,3}];//Timing
Out[54]= {0.219,Null}

In[55]:= mapAt[f,largemat,{All,3},MappedListable->True];//Timing
Out[55]= {0.031,Null}

The point is that, while f was not declared Listable, we know that its body is built out of Listable functions, and thus it can be applied to the entire list - but OTOH it can not be auto-compiled by Map. Note that adding Listable attribute to f would have been completely wrong here and would destroy the purpose, leading to mapAt being slow in both cases.

share|improve this answer
How can I not vote for this? You always bring a deeper analysis to the table. By the way, "The solution of @Mr.Wizard assumes that either a function is Listable or we want to apply it to the entire list." I thought that was the point of this question based on the example. Yours in certainly an interesting take on it. Your last paragraph highlights something I have wondered about before: is there, or does it make sense to have, some way to assert that a function as "inherently listable"? This could help with misuse case 4 here.. – Mr.Wizard Dec 21 '11 at 0:35
@Mr.Wizard I think one can implement something like the type-inference for Listability, to address this problem. This does not even sound as a very hard problem. – Leonid Shifrin Dec 21 '11 at 18:55
What do you have in mind? It is a very loosely formed idea for me at this time. – Mr.Wizard Dec 21 '11 at 19:07
@Mr.Wizard The question can be formulated as follows: given a piece of code representing a function call, determine whether or not the result will be internally parallelized by appropriate Listable kernel functions which are called during the evaluation of this piece of code. But I start to see that this is not such a simple problem as I initially thought, so I withdraw my previous statement. – Leonid Shifrin Dec 21 '11 at 19:13

How about

Transpose[{#[[All, 1]], Rescale[#[[All, 2]]]} &@data]

which returns what you want (ie, it does not alter data)

If no Transpose is allowed,

Thread[Join[{#[[All, 1]], Rescale[#[[All, 2]]]} &@data]]


EDIT: As "shortest" is now the goal, best from me so far is:

data\[LeftDoubleBracket]All, 2\[RightDoubleBracket] = Rescale[data[[All, 2]]]

at 80 characters, which is identical to Mr.Wizard's... So vote for his answer.

share|improve this answer
Is that any cleaner than what he uses now? – Mr.Wizard Dec 20 '11 at 18:37
@Mr.W well, obviously I think it is (it uses indexing rather than MapAt, transposing and indexing to locate the elements to be acted upon, don't you think this is cleaner?), but of course different people think in different ways. – acl Dec 20 '11 at 18:39
Pardon me, I didn't mean to be rude. I guess I fixated on the OP's request to "do this without so much Transposeing." – Mr.Wizard Dec 20 '11 at 18:43
@Mr.W no rudeness perceived. I agree that yours looks cleaner; less @&# going on, which is bizarre :) – acl Dec 20 '11 at 18:44
Look, @Mr.W, no Transpose! – acl Dec 20 '11 at 19:07

Here is another approach:

op[data_List, fun_] := 
 Join[data[[All, {1}]], fun[data[[All, {2}]]], 2]

op[data, Rescale]

Edit 1:

An extension from Mr.Wizard, that does not copy it's data.

SetAttributes[partReplace, HoldFirst]
partReplace[dat_, func_, spec__] := dat[[spec]] = func[dat[[spec]]];

used like this

partReplace[data, Rescale, All, 2]

Edit 2: Or like this

ReplacePart[data, {All, 2} -> Rescale[data[[All, 2]]]]
share|improve this answer
ReplacePart was the first thing I thought of, but I used {_, 2} and it failed. EDIT: Oh darn, it still doesn't work. :-(( Is this a v8 change? – Mr.Wizard Dec 21 '11 at 0:37
This works in 801 and 804. I don't have V7 handy anymore. It could be that this was fixed, but I don't know. – user1054186 Dec 21 '11 at 8:36

This worked for me and a friend

In[128]:= m = {{x, sss, x}, {y, sss, y}}
Out[128]= {{2, sss, 2}, {y, sss, y}}

In[129]:= function[ins1_] := ToUpperCase[ins1];
fatmap[ins2_] := MapAt[function, ins2, 2];

In[131]:= Map[fatmap, m]
Out[131]= {{2, ToUpperCase[sss], 2}, {y, ToUpperCase[sss], y}}
share|improve this answer

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