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Many algorithms (like the algorithm for finding the next permutation of a list in lexicographical order) involve finding the index of the last element in a list. However, I haven't been able to find a way to do this in Mathematica that isn't awkward. The most straightforward approach uses LengthWhile, but it means reversing the whole list, which is likely to be inefficient in cases where you know the element you want is near the end of the list and reversing the sense of the predicate:

findLastLengthWhile[list_, predicate_] :=
 (Length@list - LengthWhile[Reverse@list, ! predicate@# &]) /. (0 -> $Failed)

We could do an explicit, imperative loop with Do, but that winds up being a bit clunky, too. It would help if Return would actually return from a function instead of the Do block, but it doesn't, so you might as well use Break:

findLastDo[list_, pred_] :=
 Module[{k, result = $Failed},
   If[pred@list[[k]], result = k; Break[]],
   {k, Length@list, 1, -1}];

Ultimately, I decided to iterate using tail-recursion, which means early termination is a little easier. Using the weird but useful #0 notation that lets anonymous functions call themselves, this becomes:

findLastRecursive[list_, pred_] :=
   step =
      #1 == 0, $Failed,
      pred@list[[#1]], #1,
      True, #0[#1 - 1]] &},

All of this seems too hard, though. Does anyone see a better way?

EDIT to add: Of course, my preferred solution has a bug which means it's broken on long lists because of $IterationLimit.

In[107]:= findLastRecursive[Range[10000], # > 10000 &]
$IterationLimit::itlim: Iteration limit of 4096 exceeded. 
Out[107]= (* gack omitted *)

You can fix this with Block:

findLastRecursive[list_, pred_] :=
 Block[{$IterationLimit = Infinity},
    step =
       #1 == 0, $Failed,
       pred@list[[#1]], #1,
       True, #0[#1 - 1]] &},

$IterationLimit is not my favorite Mathematica feature.

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If only lists were represented as double linked structures ... – belisarius has settled Sep 16 '11 at 14:22
are you sure your first line of code is correct? Unless I'm not understanding what it is supposed to do shouldn't the second LengthWhile be LengthWhile[list//Reverse, predicate@# &]? So, adding a Reverse and removing the !? – Sjoerd C. de Vries Sep 16 '11 at 14:40
@Sjoerd C. de Vries Yes, you're right. I edited in a fix. – Pillsy Sep 16 '11 at 15:05
@Pillsy Regarding efficiency: generally (and as @belisarius demonstrated in his answer), structural operations are very fast in mma. So, while not reverting a list may be better asymptotically, you will probably need huge lists to really observe that, given that list non-reversing solutions use mma evaluator which slows them down by a large constant factor w.r.t. those using Reverse. – Leonid Shifrin Sep 16 '11 at 15:53
@Pillsy sorry to try to reach you like this, but you need to confirm your email address for the Area 51 account before you come up on the commitment list. See – Verbeia Jan 11 '12 at 23:05

6 Answers 6

up vote 6 down vote accepted

Personally, I don't see anything wrong with LengthWhile-based solution. Also, if we want to reuse mma built-in list-traversing functions (as opposed to explicit loops or recursion), I don't see a way to avoid reverting the list. Here is a version that does that, but does not reverse the predicate:

findLastLengthWhile[{}, _] = 0;
findLastLengthWhile[list_, predicate_] /; predicate[Last[list]] := Length[list];
findLastLengthWhile[list_, predicate_] :=
   Module[{l = Length[list]}, 
     Scan[If[predicate[#], Return[], l--] &, Reverse[list]]; l];

Whether or not it is simpler I don't know. It is certainly less efficient than the one based on LengthWhile, particularly for packed arrays. Also, I use the convention of returning 0 when no element satisfying a condition is found, rather than $Failed, but this is just a personal preference.


Here is a recursive version based on linked lists, which is somewhat more efficient:

ClearAll[linkedList, toLinkedList];
SetAttributes[linkedList, HoldAllComplete];
toLinkedList[data_List] := Fold[linkedList, linkedList[], data];

findLastRec[list_, pred_] :=
  Block[{$IterationLimit = Infinity},
     Module[{ll = toLinkedList[list], findLR},
       findLR[linkedList[]] := 0;
       findLR[linkedList[_, el_?pred], n_] := n;
       findLR[linkedList[ll_, _], n_] := findLR[ll, n - 1];
       findLR[ll, Length[list]]]]

Some benchmarks:

In[48]:= findLastRecursive[Range[300000],#<9000&]//Timing
Out[48]= {0.734,8999}

In[49]:= findLastRec[Range[300000],#<9000&]//Timing
Out[49]= {0.547,8999}


If your list can be made a packed array (of whatever dimensions), then you can exploit compilation to C for loop-based solutions. To avoid the compilation overhead, you can memoize the compiled function, like so:

findLastLW[predicate_, signature_] := findLastLW[predicate, Verbatim[signature]] = 
       With[{sig = List@Prepend[signature, list]},
      Compile @@ Hold[
        Module[{k, result = 0},
            If[predicate@list[[k]], result = k; Break[]], 
            {k, Length@list, 1, -1}
        CompilationTarget -> "C"]]]

The Verbatim part is necessary since in typical signatures like {_Integer,1}, _Integer will otherwise be interpreted as a pattern and the memoized definition won't match. Here is an example:

fn = findLastLW[#<9000&,{_Integer,1}];

Out[61]= {0.016,8999}


Here is a much more compact and faster version of recursive solution based on linked lists:

findLastRecAlt[{}, _] = 0;
findLastRecAlt[list_, pred_] :=
  Module[{lls, tag},
    Block[{$IterationLimit = Infinity, linkedList},
       SetAttributes[linkedList, HoldAllComplete];
       lls = Fold[linkedList, linkedList[], list];
       ll : linkedList[_, el_?pred] := Throw[Depth[Unevaluated[ll]] - 2, tag];
       linkedList[ll_, _] := ll;
       Catch[lls, tag]/. linkedList[] :> 0]]

It is as fast as versions based on Do - loops, and twice faster than the original findLastRecursive (the relevant benchmark to be added soon - I can not do consistent (with previous) benchmarks being on a different machine at the moment). I think this is a good illustration of the fact that tail-recursive solutions in mma can be as efficient as procedural (uncompiled) ones.

share|improve this answer
+1. There are advantages to returning 0, especially when dealing with Compile. – Pillsy Sep 16 '11 at 15:07
@Pillsy I usually reserve $Failed for functions doing something less algorithmic and predictable, like reading a file from disk, etc. But I think that this depends on the context in which you use it more than on the function itself. I can easily imagine that in some context returning $Failed for the problem in question will be more appropriate. I just don't think that general functions like this should do that - so in that case, I'd write a wrapper function converting 0 to $Failed. – Leonid Shifrin Sep 16 '11 at 16:01
@Pillsy I found an even faster recursive solution - please see my latest edit. – Leonid Shifrin Sep 16 '11 at 22:16

Not really an answer, just a couple of variants on findLastDo.

(1) Actually Return can take an undocumented second argument telling what to return from.

In[74]:= findLastDo2[list_, pred_] := 
 Module[{k, result = $Failed}, 
  Do[If[pred@list[[k]], Return[k, Module]], {k, Length@list, 1, -1}];

In[75]:= findLastDo2[Range[25], # <= 22 &]
Out[75]= 22

(2) Better is to use Catch[...Throw...]

In[76]:= findLastDo3[list_, pred_] := 
 Catch[Module[{k, result = $Failed}, 
   Do[If[pred@list[[k]], Throw[k]], {k, Length@list, 1, -1}];

In[77]:= findLastDo3[Range[25], # <= 22 &]
Out[77]= 22

Daniel Lichtblau

share|improve this answer
You should docuument that second argument of Return. It makes it a lot more useful! :) – Pillsy Sep 16 '11 at 15:26
@Pillsy I filed a suggestion report for this. – Daniel Lichtblau Sep 16 '11 at 15:32
Awesome, thanks! – Pillsy Sep 16 '11 at 15:44
+1 Any idea why this is undocumented? Any reasons to restrain ourselves from using it? – Sjoerd C. de Vries Sep 16 '11 at 15:56
@Sjoerd C. de Vries No idea on that. Should be safe to use, as best I am aware. I use it. – Daniel Lichtblau Sep 16 '11 at 16:04

For the adventurous...

The following definitions define a wrapper expression reversed[...] that masquerades as a list object whose contents appear to be a reversed version of the wrapped list:

reversed[list_][[i_]] ^:= list[[-i]]
Take[reversed[list_], i_] ^:= Take[list, -i]
Length[reversed[list_]] ^:= Length[list]
Head[reversed[list_]] ^:= List

Sample use:

$list = Range[1000000];
Timing[LengthWhile[reversed[$list], # > 499500 &]]
(* {1.248, 500500} *)

Note that this method is slower than actually reversing the list...

Timing[LengthWhile[Reverse[$list], # > 499500 &]]
(* 0.468, 500500 *)

... but of course it uses much less memory.

I would not recommend this technique for general use as flaws in the masquerade can manifest themselves as subtle bugs. Consider: what other functions need to implemented to make the simulation perfect? The exhibited wrapper definitions are apparently good enough to fool LengthWhile and TakeWhile for simple cases, but other functions (particularly kernel built-ins) may not be so easily fooled. Overriding Head seems particularly fraught with peril.

Notwithstanding these drawbacks, this impersonation technique can sometimes be useful in controlled circumstances.

share|improve this answer
+1 (My eyes! ). – belisarius has settled Sep 16 '11 at 16:26
+1 I don't know whether to applaud or hide under my desk! – Pillsy Sep 16 '11 at 16:40
I am not sure this uses less memory as written - the $list is anyway copied first by the system. You probably can fix this by making reversed HoldAll or HoldFirst. – Leonid Shifrin Sep 16 '11 at 17:06
@Leonid I was unable to observe a memory spike that suggested that the array was being copied. I used crude techniques like sprinkling Print@MemoryInUse[] calls in the reversed definitions and watching the virtual memory size as reported by external system tools. Can you suggest a way to observe this copying? – WReach Sep 16 '11 at 18:12
@WReach It may be my misunderstanding of how mma treats expressions internally. I thought that whenever we use something like a = Range[100];f[a], first a gets copied into some internal heap space, which is then used by f. Apparently, mma seem to copy lazily :In[66]:= MemoryInUse[] Out[66]= 11106272 In[67]:= a= Range[1000000]; In[68]:= MemoryInUse[] Out[68]= 15107248 In[69]:= b=a; In[70]:= MemoryInUse[] Out[70]= 15108536 In[71]:= b[[10]]=1; MemoryInUse[] Out[72]= 19110352. The real copying happened only when some destructive operation was performed on the list that prevented the ... – Leonid Shifrin Sep 16 '11 at 21:37

Here are some alternatives, two of which don't reverse the list:

findLastLengthWhile2[list_, predicate_] := 
 Length[list]-(Position[list//Reverse, _?(!predicate[#] &),1,1]/.{}->{{0}})[[1, 1]]+1

findLastLengthWhile3[list_, predicate_] := 
    Module[{lw = 0}, 
      Scan[If[predicate[#], lw++, lw = 0] &, list]; 
      Length[list] - lw

findLastLengthWhile4[list_, predicate_] := 
   Module[{a}, a = Split[list, predicate]; 
         Length[list] - If[predicate[a[[-1, 1]]], Length[a[[-1]]], 0]

Some timings (number 1 is Pillsy's first one) of finding the last run of 1's in an array of 100,000 1's in which a single zero is placed on various positions. Timings are the mean of 10 repeated meusurements:

enter image description here

Code used for timings:

 timings = Table[
   ri = ConstantArray[1, {100000}];
   ri[[daZero]] = 0;
   t1 = (a1 = findLastLengthWhile[ri, # == 1 &];) // Timing // First;
   t2 = (a2 = findLastLengthWhile2[ri, # == 1 &];) // Timing // First;
   t3 = (a3 = findLastLengthWhile3[ri, # == 1 &];) // Timing // First;
   t4 = (a4 = findLastLengthWhile4[ri, # == 1 &];) // Timing // First;
   {t1, t2, t3, t4},
   {daZero, {1000, 10000, 20000, 50000, 80000, 90000, 99000}}, {10}
   ], {daZero}

   Transpose[{{1000, 10000, 20000, 50000, 80000, 90000,99000}, #}] & /@ 
     (Mean /@ timings // Transpose), 
   Mesh -> All, Frame -> True, FrameLabel -> {"Zero position", "Time (s)", "", ""}, 
   BaseStyle -> {FontFamily -> "Arial", FontWeight -> Bold, 
   FontSize -> 14}, ImageSize -> 500
share|improve this answer
The problem with your list-nonreversing functions is that they traverse the list from the start, which (under assumptions that the result is likely to be found at the end) will likely be far less efficient than reversing the list and traversing that. – Leonid Shifrin Sep 16 '11 at 15:21
@Leonid True, if you happen to know that will be the case. – Sjoerd C. de Vries Sep 16 '11 at 15:27
@Leonid From my timings it looks like if you don't have a clue the fourth method has the best overall performance. – Sjoerd C. de Vries Sep 16 '11 at 15:57
These timings look a bit unexpected to me. Can you post the code you used? – Leonid Shifrin Sep 16 '11 at 16:05
@Leonid Added. I hope I didn't make a mistake. However, the timings don't look unexpected to me. Number 1 and 2 do a reverse then seek. Should do good with the zero at the end. Number 3 and 4 go through the whole list and should take a time roughly independent of the zero's position. – Sjoerd C. de Vries Sep 16 '11 at 16:18

Timing Reverse for Strings and Reals

a = DictionaryLookup[__];
b = RandomReal[1, 10^6];
Timing[Short@Reverse@#] & /@ {a, b}

{{0.016,         {Zyuganov,Zyrtec,zymurgy,zygotic,zygotes,...}},
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I get 0 for both timings. But what lesson should we learn from the above? That Reverse take longer for strings than for reals? Apparently so, as there are 10 times as much numbers as there are strings and the ByteCount of b is 8000168 and of a is 5639088. – Sjoerd C. de Vries Sep 16 '11 at 16:12
@Sjoerd I learned that Reverse could represent a problem with really large string lists, but probably not for Reals. Besides, congrats for your tachyonic CPU. – belisarius has settled Sep 16 '11 at 16:22
@Sjoerd C. de Vries: I think the lesson is that RandomReal returns a packed array, and operations on packed arrays are much faster than operations on normal lists. (And we could learn that the first call to Reverse takes slightly longer, but you probably thought to repeat the measurement a few times) – nikie Sep 16 '11 at 17:19

An elegant solution would be:

findLastPatternMatching[{Longest[start___], f_, ___}, f_] := Length[{start}]+1

(* match this pattern if item not in list *)
findLastPatternMatching[_, _] := -1

but as it's based on pattern matching, it's way slower than the other solutions suggested.

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