# Efficient way to remove empty lists from lists without evaluating held expressions?

In previous thread an efficient way to remove empty lists (`{}`) from lists was suggested:

``````Replace[expr, x_List :> DeleteCases[x, {}], {0, Infinity}]
``````

Using the Trott-Strzebonski in-place evaluation technique this method can be generalized for working also with held expressions:

``````f1[expr_] :=
Replace[expr,
x_List :> With[{eval = DeleteCases[x, {}]}, eval /; True], {0, Infinity}]
``````

This solution is more efficient than the one based on `ReplaceRepeated`:

``````f2[expr_] := expr //. {left___, {}, right___} :> {left, right}
``````

But it has one disadvantage: it evaluates held expressions if they are wrapped by `List`:

``````In[20]:= f1[Hold[{{}, 1 + 1}]]

Out[20]= Hold[{2}]
``````

So my question is: what is the most efficient way to remove all empty lists (`{}`) from lists without evaluating held expressions? The empty `List[]` object should be removed only if it is an element of another `List` itself.

Here are some timings:

``````In[76]:= expr = Tuples[Tuples[{{}, {}}, 3], 4];
First@Timing[#[expr]] & /@ {f1, f2, f3}
pl = Plot3D[Sin[x y], {x, 0, Pi}, {y, 0, Pi}];
First@Timing[#[pl]] & /@ {f1, f2, f3}

Out[77]= {0.581, 0.901, 5.027}

Out[78]= {0.12, 0.21, 0.18}
``````

Definitions:

``````Clear[f1, f2, f3];
f3[expr_] :=
FixedPoint[
Function[e, Replace[e, {a___, {}, b___} :> {a, b}, {0, Infinity}]], expr];
f1[expr_] :=
Replace[expr,
x_List :> With[{eval = DeleteCases[x, {}]}, eval /; True], {0, Infinity}];
f2[expr_] := expr //. {left___, {}, right___} :> {left, right};
``````
-

``````Clear[f3];
f3[expr_] :=
FixedPoint[
Function[e,
Replace[e, {a___, {}, b___} :> {a, b}, {0, Infinity}]],
expr]
``````

It seems to live up to the specs:

``````In[275]:= f3[{a, {}, {b, {}}, c[d, {}]}]

Out[275]= {a, {b}, c[d, {}]}

In[276]:= f3[Hold[{{}, 1 + 1, {}}]]

Out[276]= Hold[{1 + 1}]
``````
-

You can combine the solutions you mentioned with a minimal performance hit and maintain the code unevaluated by using a technique from this post, with a modification that the custom holding wrapper will be made private by using `Module`:

``````ClearAll[removeEmptyListsHeld];
removeEmptyListsHeld[expr_Hold] :=
Module[{myHold},
SetAttributes[myHold, HoldAllComplete];
x : myHold[List][___] :>
With[{eval = DeleteCases[x, myHold[myHold[List][]]]},
eval /; True],
{0, Infinity}]//. myHold[x_] :> x];
``````

The above function assumes that the input expression is wrapped in `Hold`. Examples:

``````In[53]:= expr = Tuples[Tuples[{{}, {}}, 3], 4];
First@Timing[#[expr]] & /@ {f1, f2, f3, removeEmptyListsHeld[Hold[#]] &}

Out[54]= {0.235, 0.218, 1.75, 0.328}

In[56]:= removeEmptyListsHeld[Hold[{{},1+1,{}}]]
Out[56]= Hold[{1+1}]
``````
-

I'm just a bit late with this one. ;-)

Though rather complicated this tests about an order of magnitude faster than your `f1`:

``````fx[expr_] :=
Module[{s},
expr //
Quiet[{s} /. {x_} :> ({} /. {x___} -> (# /. {} -> x //. {x ..} -> x) &)]
]
``````

It does not evaluate:

``````Hold[{{}, 1 + 1}] // fx
``````
``````Hold[{1 + 1}]
``````

### Timings

``````expr = Tuples[Tuples[{{}, {}}, 3], 4];
First @ Timing @ Do[# @ expr, {100}] & /@ {f1, fx}

pl = Plot3D[Sin[x y], {x, 0, Pi}, {y, 0, Pi}];
First @ Timing @ Do[# @ pl, {100}] & /@ {f1, fx}
``````
``````{10.577, 0.982}  (* 10.8x faster *)

{1.778, 0.266}   (* 6.7x faster  *)
``````

### Check

``````f1@expr === fx@expr
f1@pl   === fx@pl
``````
``````True

True
``````

### Explanation

The basic version of this function would look like this:

``````{} /. {x___} -> (# //. {} | {x ..} -> x) &
``````

The idea is to first reduce the expression with `//. {} | {x ..} -> x` and then use the injector pattern with an empty expression to remove all instances of `x`, as though they were replaced with `Sequence[]` but without evaluation.

The first change is to optimize this somewhat by splitting the replacement into `/. {} -> x //. {x ..} -> x`. The second change is to somehow localize `x` in the patterns so that it does not fail if `x` appears in the expression itself. Because of the way Mathematica handles nested scoping constructs I cannot simply use `Module[{x}, . . . ]` but instead have to use the injector pattern again to get a unique symbol into `x___` etc., and `Quiet` to keep it from complaining about the nonstandard use.

-
+1 This solution is really esoteric. Could you please explain which value `x` takes on different levels of nested `ReplaceAll` and `ReplaceRepeated`? And what happens to the variable `s`? –  Alexey Popkov Oct 23 '12 at 3:06
@Alexey for some reason I didn't get notified of this comment. If you look at the "basic version" it's not too complicated. `(# //. {} | {x ..} -> x)` replaces any empty lists with `x`, and any lists like `{x, x, x}` also with `x`. Then this becomes the right and side of a replacement `{x___} ->` which "injects" a certain expression to replace every `x`, with the trick being `{} /. {x___}` such that `x` is replaced by nothing. (continued) –  Mr.Wizard Oct 25 '12 at 3:45
A second injection is used in the `Module` to replace every literal `x` in the pattern with a unique symbol to form a function like: `{} /. {s\$152___} -> (#1 /. {} -> s\$152 //. {s\$152 ..} -> s\$152) &` which is what actually does the job. I don't have time to give a longer explanation and I may not for a few days so this will have to suffice for now; I hope it helps. –  Mr.Wizard Oct 25 '12 at 3:47