When trying to simulate the evaluation behavior of RuleDelayed I faced unexpected behavior of nested Unevaluated. Consider:

In[1]:= f[Verbatim[Unevaluated][expr_]] := f[expr]
f[Unevaluated[1 + 1]]
f[Unevaluated@Unevaluated[1 + 1]]
f[Unevaluated@Unevaluated@Unevaluated[1 + 1]]
f[Unevaluated@Unevaluated@Unevaluated@Unevaluated[1 + 1]]

Out[2]= f[Unevaluated[1 + 1]]

Out[3]= f[2]

Out[4]= f[Unevaluated[1 + 1]]

Out[5]= f[2]

One can see that only even number of nested Unevaluated wrappers are completely removed. Why?


Use Trace to see why:

In[1]:= f[Verbatim[Unevaluated][expr_]]:=f[expr]

In[2]:= f[Unevaluated[1+1]]//Trace
Out[2]= {f[1+1],f[Unevaluated[1+1]]}
  1. Due to the defining special property of the Unevaluated language construct, f[Unevaluated[1 + 1]] evaluates just like f[1 + 1] except the 1 + 1 is left unevaluated.
  2. f[1 + 1] does not match the definition you gave for f.
  3. Therefore f[Unevaluated[1 + 1]] remains unevaluated.


In[3]:= f[Unevaluated@Unevaluated[1 + 1]] // Trace
Out[3]= {f[Unevaluated[1+1]],f[1+1],{1+1,2},f[2]}
  1. Due to the defining special property of the Unevaluated language construct, f[Unevaluated@Unevaluated[1 + 1]] evaluates just like f[Unevaluated[1 + 1]] except the Unevaluated[1 + 1] is left unevaluated.
  2. f[Unevaluated[1 + 1]] matches the definition you gave for f, and evaluates to f[1 + 1].
  3. Therefore f[Unevaluated@Unevaluated[1 + 1]] evaluates to f[2].
  • Wow I literally beat you to the answer by seconds =) – Michael Pilat Jun 8 '11 at 6:10
  • Yeah! Nice coincidence for an hour old question. I like your answer better overall. – Andrew Moylan Jun 8 '11 at 6:17
  • Very clear explanation, thank you! Both answers are great and complement each other, but your explanation in the form of a sequence of decisions taken by the evaluator is more schematic and easier to remember. So I accept your answer. – Alexey Popkov Jun 8 '11 at 7:35

The key is that, effectively, one layer of Unevaluated is removed before the expression is pattern-matched. From the docs:

f[Unevaluated[expr]] effectively works by temporarily setting attributes so that f holds its argument unevaluated, then evaluating f[expr].

Thus, in the first case, f[Unevaluated[1 + 1]] is evaluated as f[1 + 1], but remaining unevaluated during pattern matching even though f lacks Hold* attributes, and since nothing matches f[1 + 1], the original expression (pre-pattern-matching) is returned unevaluated.

In the second case, f[Unevaluated[Unevaluated[1 + 1]]] evaluates as f[Unevaluated[1 + 1]] in the pattern-matcher, which does match a pattern for f, and then f[1 + 1] is evaluated recursively, and thus you get f[2].

In the third case, f[Unevaluated[Unevaluated[Unevaluated[1 + 1]]]] evaluates as f[Unevaluated[Unevaluated[Unevaluated[1 + 1]]]], matches, and recursively evaluates as f[Unevaluated[1 + 1]], and we're back to the first case.

In the fourth case, f[Unevaluated[Unevaluated[Unevaluated[Unevaluated[1 + 1]]]]] matches on f[Unevaluated[Unevaluated[Unevaluated[1 + 1]]]], recursively evaluates f[Unevaluated[Unevaluated[1 + 1]]], and we're back to the second case.


Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.