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One can test if an argument is a Symbol without a explicit value using:

func[s_Symbol] = ...

If the function has a Hold attribute however, that pattern will match all Symbols, not only those without an explicit value. I could use:

func[s_] /; Head[s] === Symbol = ...

but this comes with a greater performance penalty than I would like. Adding a rule for _Symbol has a fairly small impact on performance, and HoldFirst does not appear to have any performance penalty, however Head[s] === Symbol has a significant overhead on a simple function. Tests with ValueQ and MatchQ[s, _Symbol] are even slower.

To clarify, I want to have two different definitions for func , with one for unassigned Symbols, and one for other arguments.

Is there a faster way?


f[x_] = 0;

f /@ Range@1*^6; // Timing

f[s_Symbol] = 1;

f /@ Range@1*^6; // Timing
   {0.391, Null}
   {0.531, Null}
SetAttributes[f, HoldFirst]

f[x_] = 0;

f /@ Range@1*^6; // Timing

f[s_] /; Head[s] === Symbol = 1;

f /@ Range@1*^6; // Timing
   {0.39, Null}
   {1.157, Null}
share|improve this question
Interesting factoid. Didn't realize type checking came with such an overhead. –  Sjoerd C. de Vries May 1 '11 at 11:58
@Sjoerd I didn't mean this as a factoid, it's a real question. Most functions are complex enough for the overhead to be comparatively small, but in simple cases it can be considerable. –  Mr.Wizard May 1 '11 at 12:00
@Sjoerd While we are at it, let me mention that there are cases when the proper use of the pattern-matcher for type-checking is crucial. Consider: tst = Range[10^6]; MatchQ[tst, {__Integer}] // Timing ; And @@ Map[Head[#] === Integer &, tst] // Timing. This is cheating a bit since the dramatic difference is due to the packed nature of an array, but you can still get a factor of 10 or something even when array is not packed. This is important when you need, for example, to determine that the input to a function is a list of integers, for a large list. –  Leonid Shifrin May 1 '11 at 15:54
@Sjoerd - I never heard of the word 'Factoid' but I like it because it sounds like 'Groupoid'. Anyway, I checked the meaning: " A factoid is a questionable or spurious—unverified, incorrect, or fabricated—statement presented as a fact, but with no veracity. " - Hmmm. –  ndroock1 Jun 11 '11 at 20:16
@ndroock1 interesting; "factoid" is similar to "verbage" in that I have heard both used incorrectly, in place of "fact" and "verbiage." –  Mr.Wizard Jun 11 '11 at 22:15

3 Answers 3

up vote 4 down vote accepted

Using pattern s_Symbol in the code with HoldFirst attribute will improve the performance:

In[121]:= Remove[f]
SetAttributes[f, HoldFirst]
f[s_Symbol] /; Head[s] === Symbol = 1;
f[_] = 0;

In[125]:= f /@ Range@1*^6; // Timing

Out[125]= {1.217, Null}

In[130]:= Remove[f2]
f2[s_Symbol] = 1;
f2[_] = 0;

In[133]:= f2 /@ Range@1*^6; // Timing

Out[133]= {1.123, Null}
share|improve this answer
I thought this would make things slower because it was in effect checked twice. I should know by know it's always best with Mathematica to test and see. +1 –  Mr.Wizard May 1 '11 at 22:15
@Mr.Wizard The reason why usign s_Symbol improves performance is that it serves to reject explicit non-symbols quickly. –  Sasha May 2 '11 at 0:13

You can get performance comparable to the fastest exhibited running times by delegating held symbol arguments to a non-held helper function g:

Remove[f, g]
SetAttributes[f, HoldFirst]
f[_] = 0;
f[s_Symbol] := g[s]
g[_Symbol] = 1;
g[_] = 0;
share|improve this answer
+1 - an elegant solution! –  Leonid Shifrin May 1 '11 at 15:46
Unlike Shasha's method, which I foolishly rejected before trying, I didn't even consider this. Like many great ideas, it seems very simple after the fact. –  Mr.Wizard May 1 '11 at 22:19

You can get it faster with this:

SetAttributes[f, HoldFirst]
f[x_] = 0;
f[s_Symbol] /; OwnValues[s] =!= {} = 1;

To compare, here is the one you used:

SetAttributes[ff, HoldFirst]
ff[x_] = 0;
ff[s_] /; Head[s] === Symbol = 1;


In[30]:= f /@ Range@1*^6; // Timing

Out[30]= {0.719, Null}

In[56]:= ff /@ Range@1*^6; // Timing

Out[56]= {1.25, Null}

This will be more effective when your arguments will mostly be non-symbols, and the reason that it is faster is that you can still use the _Symbol pattern to filter them out. For lists of symbols only, it may actually be slower:

symbTest = Table[ToExpression["sym" <> ToString[i]], {i, 100000}];
MapIndexed[If[OddQ[First@#2], #1 = First@#2] &, symbTest];

In[54]:= ReleaseHold[Map[f,Hold[symbTest]/.OwnValues[symbTest],{2}]]//Short//Timing
Out[54]= {0.234,{1,0,1,0,1,0,1,0,1,0,1,0,1,0,1,0,1,0,<<99964>>,1,0,1,0,1,0,1,0,1,0,1,0,1,0,1,0,1,0}}

In[58]:= ReleaseHold[Map[ff,Hold[symbTest]/.OwnValues[symbTest],{2}]]//Short//Timing
Out[58]= {0.141,{0,1,0,1,0,1,0,1,0,1,0,1,0,1,0,1,0,1,<<99964>>,0,1,0,1,0,1,0,1,0,1,0,1,0,1,0,1,0,1}}
share|improve this answer
Interesting use of OwnValues here, and a good analysis of list contents. Any thoughts regarding f[s_Symbol] /; Head[s] === Symbol versus f[s_Symbol] /; OwnValues[s] =!= {}? –  Mr.Wizard May 1 '11 at 22:24
@Mr.Wizard My testing show that the test Head[s] === Symbol is a wee faster on x = Fold[{#1, {#2}} &, 0, Range[10000]];. Then Do[TestWithOwnValues[x], {10^6}] // AbsoluteTiming gives 2.9 seconds, while Do[TestWithHead[x], {10^6}] // AbsoluteTiming completes in 2.4 seconds. –  Sasha May 2 '11 at 0:12
@Sasha, @Mr.Wizard But @Sasha's observation is exactly what I also warned about in the answer - the point is not in the use of OwnValues, but in the ability to still filter out non-symbols or symbols with values fast. If anything, this tells us about the pattern-matcher internals: explicit patterns like _Symbol are obviously checked before the test in Condition is computed, which makes perfect sense to me. –  Leonid Shifrin May 2 '11 at 8:11

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