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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__]?

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up vote 12 down vote accepted

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

Here's a possible implementation:

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

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


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.

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SetAttributes[My`Print, HoldAll]
My`Print[args___] := 
      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]

(* ==>
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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 ... ` – Leonid Shifrin Nov 4 '11 at 9:18
... 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]. – Leonid Shifrin Nov 4 '11 at 9:21
@Leonid True, should have given it more thought. – Sjoerd C. de Vries Nov 4 '11 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. – Leonid Shifrin Nov 4 '11 at 23:32
SetAttributes[MyPrint, HoldAll];
MyPrint[var_] := 
    {varname = ToString[Hold[var]]},
    Print[StringTake[varname, {6, StringLength[varname] - 1}], 
                " = ", Evaluate[var]]
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Didn't see Szabolcs's code before I did this. Anyway, I'll leave it up as another sample. – Kevin O'Bryant Nov 2 '11 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. – Sjoerd C. de Vries Nov 2 '11 at 20:38

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

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}
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+1. Very clear! But ToString is not necessary - Print[HoldForm[arg], " = ", arg] is sufficient. – Alexey Popkov Nov 4 '11 at 3:06
@Alexey Good catch! Edited. – Leonid Shifrin Nov 4 '11 at 9:06
+1 very elegant, although the {Null,Null,Null} output is a small blemish – Sjoerd C. de Vries Nov 4 '11 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. – Leonid Shifrin Nov 4 '11 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 ;-) – Sjoerd C. de Vries Nov 5 '11 at 11:36

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

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

... and another...

SetAttributes[My`Print, HoldAll]
My`Print[args___] :=
    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
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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}

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