11

I'd like to create a function My`Print[args__] that prints the names of the symbols that I pass it, along with their values. The problem is that before the symbols are passed to My`Print, they're evaluated. So My`Print never gets to see the symbol names.

One solution is to surround every argument that I pass to My`Print with Unevaluated[], but this seems messy. Is there a way of defining a MACRO such that when I type My`Print[args__], the Mathematica Kernel sees My`Print[Unevaluated /@ args__]?

6 Answers 6

15

You need to set the attribute HoldAll on your function, with SetAttribute[my`print].

Here's a possible implementation:

Clear[my`print]
SetAttributes[my`print, HoldAll]
my`print[args__] := 
 Scan[
  Function[x, Print[Unevaluated[x], " = ", x], {HoldAll}], 
  Hold[args]
 ]

I used lowercase names to avoid conflicts with built-ins or functions from packages.

EDIT:

Just to make it explicit: I have two functions here. One will print the value of a single symbol, and is implemented as a Function inside. You can just use this on its own if it's sufficient. The other is the actual my`print function. Note that both need to have the HoldAll attribute.

10
ClearAll[My`Print]
SetAttributes[My`Print, HoldAll]
My`Print[args___] := 
 Do[
   Print[
      Extract[Hold[args], i, HoldForm], "=", List[args][[i]]
   ], {i, Length[List[args]]}
 ]

ape = 20;
nut := 20 ape;
mouse = cat + nut;

My`Print[ape, nut, mouse]

(* ==>
ape=20
nut=400
mouse=400+cat
*)
4
  • 1
    Two notes. First one is very non-obvious - check out this code: i = 0;My`Print[i++]. A generated error message is puzzling and is due to Do using dynamic scoping (a-la Block) to localize its variables (i here). The executed code happens to modify i, which has an effect only until the next loop iteration resets i back - but here this matters. You can avoid this by wrapping SetDelayed in Module[{i},...] when defining the function. The second note: by wrapping args in List, you evaluate them several times, which may not be desirable if their execution trigger ... ` Commented Nov 4, 2011 at 9:18
  • 1
    ... side effects. For example, here: i = j = k = 0;My`Print[i++, j++, k++];{i, j, k}, you get outputs i++=1, j++ = 1, k++ = 3 and at the end, all of i,j,k are set to 4. You can avoid this by always using Hold[args]. Commented Nov 4, 2011 at 9:21
  • @Leonid True, should have given it more thought. Commented Nov 4, 2011 at 22:17
  • The first one I discovered by pure chance, naming one of the variables accidentally as i. I did not expect this (although it is logical in retrospect), and it took me a while to understand. In any case, neither one detracts from your answer, which I upvoted. Philosophically, though, this confirms that with shorter and higher-level code we also have fewer chances for bugs. Commented Nov 4, 2011 at 23:32
9
SetAttributes[MyPrint, HoldAll];
MyPrint[var_] := 
  Module[
    {varname = ToString[Hold[var]]},
    Print[StringTake[varname, {6, StringLength[varname] - 1}], 
                " = ", Evaluate[var]]
  ]
2
  • Didn't see Szabolcs's code before I did this. Anyway, I'll leave it up as another sample. Commented Nov 2, 2011 at 18:18
  • Apart from the HoldAll there is almost no overlap between Szabolcs' and your method. No need for excuses I'd say, the more varieties the better. Commented Nov 2, 2011 at 20:38
6

Coming late to the party - one can use Listability to get a rather elegant (IMO) solution avoiding explicit loops or evaluation control constructs:

ClearAll[prn];
SetAttributes[prn, {HoldAll, Listable}];
prn[arg_] := Print[HoldForm[arg], " = ", arg];
prn[args___] := prn[{args}]

Stealing the test case from @Sjoerd,

In[21]:= prn[ape,nut,mouse]

During evaluation of In[21]:= ape = 20
During evaluation of In[21]:= nut = 400
During evaluation of In[21]:= mouse = 400+cat

Out[21]= {Null,Null,Null}
8
  • 2
    +1. Very clear! But ToString is not necessary - Print[HoldForm[arg], " = ", arg] is sufficient. Commented Nov 4, 2011 at 3:06
  • +1 very elegant, although the {Null,Null,Null} output is a small blemish Commented Nov 4, 2011 at 22:16
  • @Sjoerd Indeed, I could have suppressed the output by wrapping prn[{args}] in extra (...);, but this would look ugly :). One can call the function with a semicolon at the end, as an alternative. Commented Nov 4, 2011 at 23:35
  • I also like how you make the function valid for use with multiple arguments. It has one disadvantage though: try prn[{ape, nut, mouse}, sheep]. I know this is a bit farfetched, but it's not that different from passing an iterator as an argument ;-) Commented Nov 5, 2011 at 11:36
  • @Sjoerd Yes, you are right. But for me, this is more a flaw of the error-checking in my function, rather than of the core approach, since such arguments are not supposed to be passed. I could change the pattern from args___ to args:(Except[_List]...), and presumably exclude the troublesome case you mention (I did not check). Commented Nov 6, 2011 at 15:57
5

Here is another variation of My`Print to add to the mix:

ClearAll[My`Print]
SetAttributes[My`Print, HoldAll]
My`Print[expr_] := Print[HoldForm[expr], " = ", expr]
My`Print[exprs___] := Scan[My`Print, Hold[exprs]]

... and another...

ClearAll[My`Print]
SetAttributes[My`Print, HoldAll]
My`Print[args___] :=
  Replace[
    Unevaluated @ CompoundExpression @ args
  , a_ :> Print[HoldForm[a], " = ", a]
  , {1}
  ]

Either way, the use is the same:

$x = 23;
f[x_] := 1 + x

My`Print[$x, $x + 1, f[1]]

(* prints:
   $x = 23
   $x+1 = 24
   f[1] = 2
*)
2

In addition to the other answers consider the functions DownValues, OwnValues and UpValues:

In[1] := f[x_] := x^2

In[2] := f[x_, y_] := (x + y)^2

In[3] := DownValues[f]

Out[3] = {HoldPattern[f[x_]] :> x^2, HoldPattern[f[x_, y_]] :> (x + y)^2}

http://reference.wolfram.com/mathematica/ref/DownValues.html

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