# Using nested slots (#)

Suppose I want to construct something like

``````Array[#1^#2 == 3 &, {3, 3}]
``````

And now I want to replace the "3" with a variable. I can do, for example:

``````f[x_] := Array[#1^#2 == x &, {x, x}]
``````

The question is: Is there a way using only slots and & as the functional notation?

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This got me looking at the docs for `Slot` (+1). The recursive, pure function definition for the factorial: `f = If[#1 == 1, 1, #1 #0[#1 - 1]]&` is pretty slick! – Simon Feb 7 '11 at 11:51
@Simon Yep. That #0 worried me too :D – belisarius has settled Feb 7 '11 at 11:57
@Simon, I've never read the Slot documentation that closely before. The `#0` is definitely bothersome, and potentially very useful. – rcollyer Feb 7 '11 at 13:21
@belisarius does a solution have to use `Array`? I think the function `Table` could meet your current requirements? – dbjohn Feb 7 '11 at 13:41
@dbjohn For example the equivalent to `f[x_] := Sort[x, #1 > #2 Last@x &]` Such as `f[{7, 3, 2}]={7,2,3}` – belisarius has settled Feb 7 '11 at 19:09

``````Map[Last, #] & /@ Array[#1^#2 == #3 &, {#, #, #}] &[3]
``````

Horrendously ugly element extraction, and very interestingly `Map[Last, #]&` gives me a different result than `Last /@`. Is this due to the fact that `Map` has different attributes than `&`?

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Map[Last, #] & /@ === (Last /@ #) & /@ != Last /@ – belisarius has settled Feb 7 '11 at 11:53
Nice hack, BTW! – belisarius has settled Feb 7 '11 at 11:55
Thanks for the explanation. – Timo Feb 7 '11 at 13:59

Not really the answer to the original question, but I noticed that many people got interested in `#0` stuff, so here I put a couple of non-trivial examples, hope they will be useful.

Regarding the statement that for nested functions one should use functions with named arguments: while this is generally true, one should always keep in mind that lexical scoping for pure functions (and generally) is emulated in Mathematica, and can be broken. Example:

``````In[71]:=
Clear[f,g];
f[fun_,val_]:=val/.x_:>fun[x];
g[fn_,val_]:=f[Function[{x},fn[#1^#2==x&,{x,x}]],val];
g[Array,3]

During evaluation of In[71]:= Function::flpar: Parameter specification {3} in
Function[{3},Array[#1^#2==3&,{3,3}]] should be a symbol or a list of symbols. >>
During evaluation of In[71]:= Function::flpar: Parameter specification {3} in
Function[{3},Array[#1^#2==3&,{3,3}]] should be a symbol or a list of symbols. >>

Out[74]= Function[{3},Array[#1^#2==3&,{3,3}]][3]
``````

This behavior has to do with the intrusive nature of rule substitutions - that is, with the fact that `Rule` and `RuleDelayed` don't care about possible name collisions between names in scoping constructs which may be present in expressions subject to rule applications, and names of pattern variables in rules. What makes things worse is that `g` and `f` work completely fine when taken separately. It is when they are mixed together, that this entanglement happens, and only because we were unlucky to use the same pattern variable `x` in the body of `f`, as in a pure function. This makes such bugs very hard to catch, while such situations do happen sometimes in practice, so I'd recommend against passing pure functions with named arguments as parameters into higher-order functions defined through patterns.

Edit:

Expanding a bit on emulation of the lexical scoping. What I mean is that, for example, when I create a pure function (which is a lexical scoping construct that binds the variable names in its body to the values of passed parameters), I expect that I should not be able to alter this binding after I have created a function. This means that, no matter where I use `Function[x,body-that-depends-on-x]`, I should be able to treat it as a black box with input parameters and resulting outputs. But, in Mathematica, `Function[x,x^2]` (for instance) is also an expression, and as such, can be modified like any other expression. For example:

``````In[75]:=
x = 5;
Function[Evaluate[x],x^2]

During evaluation of In[75]:= Function::flpar: Parameter specification 5 in Function[5,x^2] should
be a symbol or a list of symbols. >>
Out[76]= Function[5,x^2]
``````

or, even simpler (the essence of my previous warning):

``````In[79]:= 1/.x_:>Function[x,x^2]

During evaluation of In[79]:= Function::flpar: Parameter specification 1 in Function[1,1^2] should
be a symbol or a list of symbols. >>

Out[79]= Function[1,1^2]
``````

I was bitten by this last behavior a few times pretty painfully. This behavior was also noted by @WReach at the bottom of his post on this page - obviously he had similar experiences. There are other ways of breaking the scope, based on exact knowledge of how Mathematica renames variables during the conflicts, but those are comparatively less harmful in practice. Generally, I don't think these sorts of things can be avoided if one insists on the level of transparency represented by Mathematica expressions. It just seems to be "over-transparent" for pure functions (and lexical scoping constructs generally), but on the other hand this has its uses as well, for example we can forge a pure function at run-time like this:

``````In[82]:= Block[{x},Function@@{x,Integrate[HermiteH[10,y],{y,0,x}]}]

Out[82]= Function[x,-30240 x+100800 x^3-80640 x^5+23040 x^7-2560 x^9+(1024 x^11)/11]
``````

Where the integral is computed only once, at definition-time (could use `Evaluate` as well). So, this looks like a tradeoff. In this way, the functional abstraction is better integrated into Mathematica, but is leaky, as @WReach noted. Alternatively, it could have been "waterproof", but perhaps for the price of being less exposed. This was clearly a design decision.

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@Leonid Thanks for the nice explanation and examples. I think this stackoverflow.com/questions/4198961/… is a good place to post it, and perhaps you may contribute there with other ideas too. – belisarius has settled Feb 7 '11 at 15:32
@belisarius Thanks, I was not sure where to put things like this. Do you think it is a good idea to relocate this post there and link to it from here? And if yes, how do I relocate the post - should I just delete it here and post there? – Leonid Shifrin Feb 7 '11 at 15:40
@Leonid I think you may post it there and leave here an answer basically with the first paragraph and a pointer to the other answer. I (hopefully "We") would like to collect in the toolbag post useful recipes and clarifying concepts. I'm sure you may help a lot with that! Also note that the in the question we are collecting an index, if you already have edit rights, feel free to maintain the index updated, or we'll do that for you if you still can't. – belisarius has settled Feb 7 '11 at 15:48
@belisarius Thanks for the explanation - done for the post. As for the index - you mean the list of books etc at the top of the page, right? - I will contribute a few entries soon. – Leonid Shifrin Feb 7 '11 at 16:16
@Leonid 1) Great! 2) Yes, I mean that index. 3) Could you explain further lexical scoping is emulated? – belisarius has settled Feb 7 '11 at 16:27

I guess you know what the documentation says about nested pure functions.

Use explicit names to set up nested pure functions (for example):

`Function[u, Function[v, f[u, v]]][x]`

Anyway, here's the best I could come up with without following the above advice:

``````f[x_] := Array[#1^#2 == x &, {x, x}]
g = Array[With[{x = #}, #1^#2 == x &], {#, #}] &
``````

`g` is functionally identical to your original `f`, but is not really better than the recommended

``````h = Function[x, Array[#1^#2 == x &, {x, x}]]
``````
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Yes, I'm aware of the docs :D. Nevertheless this case, where I want to use the same variable value for the inner and outer parms seems prone to some hacking. – belisarius has settled Feb 7 '11 at 11:51
@belisarius: Actually, I didn't notice it was you who asked the question. Sorry! – Simon Feb 7 '11 at 11:53
next time I'll include a `nice portrait` to ease recognition :D – belisarius has settled Feb 7 '11 at 12:07

Perhaps

``````Array[#1^#2 &, {#, #}] /. i_Integer :> i == # &[3]
``````

Or

``````Thread /@ Thread[# == Array[#1^#2 &, {#, #}]] &[3]
``````
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+1 I really like the first one – belisarius has settled Feb 16 '11 at 0:59
@belisarius Thank you. :-) It is very gratifying that a noob like me has anything at all to offer a 13.7K rep grandmaster. – Mr.Wizard Feb 16 '11 at 5:10
You'll often see here great questions and answers posted by people with very few rep points. Don't get fooled by the numbers, you'll find users with a superior knowledge of Mma , and much lower rep. BTW: welcome! – belisarius has settled Feb 16 '11 at 6:24
@belisarius look, I've got 13.7K rep now. :-) – Mr.Wizard Dec 8 '11 at 11:39
:D As I said: Don't get fooled by the numbers :DD Congrats! – belisarius has settled Dec 8 '11 at 12:37

How about `With[{x = #1}, Array[#1^#2 == x &, {x, x}]] &`?

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+1. Yes, this is one of the possibilities. Actually, I use this construct quite often when I need to nest slot-based functions, and I know that some other folks use this too. – Leonid Shifrin Jun 22 '13 at 16:56
Named argument is somehow necessary. Well, anonymous function has limitations when facing nest construct. Good lesson for me newbie! – Life Jun 22 '13 at 17:05
`Sequence[x, Array[#1^#2 == x &, {x, x}]] &` is also a skill. – Life Jun 22 '13 at 17:12