# Efficient way to remove empty lists from lists?

What is the most efficient way to remove all empty `List[]` objects from all of the `List`s that appear in an expression at different levels? The empty `List[]` should be removed only if it is an element of another `List` itself.

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Andrew and Alexey point out that using `expr //. x_List :> DeleteCases[x, {}, Infinity]` as I had in my previous answer will also remove the `{}` in `blah[{f[{}]}]`, whereas it should leave it untouched as its head is `f`, not a `List`. The solution, thanks to Leonid, is to not use `ReplaceRepeated`, but `Replace` instead with replacements being made at all levels from `0` through `Infinity`:

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

The reason why `Replace` works and `ReplaceRepeated` doesn't can be seen from this little example. Consider `expr = {a, {}, {b, {}}, c[d, {}]};` in its `TreeForm`

`Replace` works by starting with the innermost expression(s) first, i.e., `List[b,{}]` and `c[d,{}]`, and works upwards to the top node. At each level, checking the head is as simple as looking up to the node right above and see if it matches `List`. If it does, apply the rule and move up a level, else do nothing and move up a level. This results in a final tree:

`ReplaceRepeated` (`//.)`, on the other hand, works by starting with the top most node and traversing down the tree. The previous solution starts by checking if the first node is a `List` and if it is, then `DeleteCases` is applied and it moves down the tree, ruthlessly replacing every `{}` it can find. Note that it does not check if the heads of the inner expressions also match `List`, because this traversal is done by `DeleteCases`, not `ReplaceRepeated`. When `//.` moves to subsequent lower nodes, there is nothing more to replace and it exits quickly. This is the tree that one gets with the previous solution:

Note that the `{}` inside `c[d, {}]` has also been removed. This is solely due to the fact that `DeleteCases` (with level specification `{0,Infinity}` moves down the tree. Indeed, if the first head had been something other than `List`, it would've skipped it and moved to the next level, of which only the `{}` in `{b, {}}` is a match. To demostrate with `expr2 = f[a, {}, {b, {}}, c[d, {}]]`, we get

Note that in the current solution with `Replace`, we use `DeleteCases` with the default level specification, which is the first level only. It does not, therefore, check for and delete empty lists deeper than on the first level, which is exactly what we need here.

Although we used the first node to explain why it fails, the reasoning holds true for every node. Leonid explains these concepts in greater detail in his book

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This will also remove empty lists inside heads other than lists, and thus contradict the specs. –  Leonid Shifrin Jul 3 '11 at 16:32
Your new solution is great, very efficient. Much faster than either of mine. +1. –  Leonid Shifrin Jul 3 '11 at 16:57
Doesn't work correct on `blah[a, b, {{{}}}, d, {e, f, {}, g}] //. x_List :> DeleteCases[x, {}]` ==> `blah[a, b, {{{}}}, d, {e, f, g}]`. Add `Infinity` to `DeleteCases`. –  Sjoerd C. de Vries Jul 3 '11 at 23:26
@yoda, @Alexey, @Sjoerd It seems that all that is needed to cure @yoda's solution is to use `Replace`: `Replace[expr, x_List :> DeleteCases[x, {}], {0, Infinity}]`. Since `Replace` acts from bottom to top (depth-first), unlike `ReplaceRepeated`, the problem is then naturally solved. It is much slower than the `DeleteCases[expr,{}]` version however. As a side product, you don't need a repeated rule application. I discussed the differences between `Replace` and `ReplaceRepeated` here: mathprogramming-intro.org/book/node218.html. This appears to be a good problem to illustrate it. –  Leonid Shifrin Jul 4 '11 at 8:16
@Alexey Did you test your suggestion? It does not seem to work. Try any of the test cases, say `{{{}}}` or `blah[a, b, {{{}}}, d, {e, f, {}, g}]`. The problem is that, if no evaluation happens (which is the case for these test cases), sub-evaluations induced by `Replace` restore the `Unevaluated` wrappers. Therefore, for inert expressions, `Unevaluated` does not buy you anything, just spoils things. If you want to perform the list deletion operation on a piece of code that may evaluate, this is a separate problem. –  Leonid Shifrin Jul 4 '11 at 9:13