# Left vs Right linked list, Replace speed

There are two obvious ways to structure a linked list in Mathematica, "left":

``````{1, {2, {3, {4, {5, {6, {7, {}}}}}}}}
``````

And "right":

``````{{{{{{{{}, 7}, 6}, 5}, 4}, 3}, 2}, 1}
``````

``````toLeftLL = Fold[{#2, #} &, {}, Reverse@#] & ;

toRightLL = Fold[List, {}, Reverse@#] & ;
``````

If I use these, and do a simple `ReplaceRepeated` to walk through the linked list, I get drastically different `Timing` results:

``````r = Range[15000];
left = toLeftLL@r;
right = toRightLL@r;

Timing[i = 0; left //. {head_, tail_} :> (i++; tail); i]
Timing[i = 0; right //. {tail_, head_} :> (i++; tail); i]

(* Out[6]= {0.016, 15000} *)

(* Out[7]= {5.437, 15000} *)
``````

Why?

-
I guess it can be faster because of tail call optimization. –  Andrey Apr 27 '11 at 0:29
Check this one: stackoverflow.com/questions/4481301/… –  Andrey Apr 27 '11 at 0:33
@Mr. Wizard: Could you break down the RHS of your `RuleDelayed`. Although I think I sort of see how it walks through the list, it's not entirely clear. Also, if I replace `tail` in the RHS with `tail-tail+tail`, I get an error: `\$RecursionLimit::reclim: Recursion depth of 256 exceeded. >>` and need to abort. Why doesn't mma figure out that `tail-tail+tail=tail` and return the same result as before? –  yoda Apr 27 '11 at 1:44
@yoda, for a "left" list, `{head_, tail_} :> (i++; tail)` increments `i` and returns the rest of the linked list, without the first element (head), e.g. `{2, {3, {4, {5, {6, {7, {}}}}}}}` if used on the first list in my question. I increment `i` simply to prove that this replacement took place 15,000 times in each case. The pattern `head_` was used only for clarity and could be replaced with `_` just as well. Since `tail` is a list structure, and arithmetic operations thread through such trees, you are doing up to 14,999 operations rather than one with each `+` or `-`. –  Mr.Wizard Apr 27 '11 at 2:09
aah `//.`!! I wasn't careful in noticing it and was trying to wrap my head around how the walk-through is done with `/.` That didn't make much sense! Now that I see it, it's clear! Thanks for the explanation on the second part of the comment. –  yoda Apr 27 '11 at 4:01

`ReplaceRepeated` uses `SameQ` to determine when to stop applying the rule.

When `SameQ` compares two lists, it checks lengths, and if the same, then applies `SameQ` to elements from the first to the last. In the case of `left` the first element is an integer, so it is easy to detect distinct lists, while for `right` list the first element is the deeply nested expression, so it needs to traverse it. This is the reason for the slowness.

``````In[25]:= AbsoluteTiming[
Do[Extract[right, ConstantArray[1, k]] ===
Extract[right, ConstantArray[1, k + 1]], {k, 0, 15000 - 1}]]

Out[25]= {11.7091708, Null}
``````

Now compare this with:

``````In[31]:= Timing[i = 0; right //. {tail_, head_} :> (i++; tail); i]

Out[31]= {5.351, 15000}
``````

EDIT In response to Mr.Wizard's question of options to speed this up. One should write a custom same testings. `ReplaceRepeated` does not provide such an option, so we should use `FixedPoint` and `ReplaceAll`:

``````In[61]:= Timing[i = 0;
FixedPoint[(# /. {tail_, _} :> (i++; tail)) &, right,
SameTest ->
Function[
If[ListQ[#1] && ListQ[#2] &&
Length[#1] ==
Length[#2], (#1 === {} && #2 === {}) || (Last[#1] ===
Last[#2]), #1 === #2]]]; i]

Out[61]= {0.343, 15000}
``````

EDIT2: Faster yet:

``````In[162]:= Timing[i = 0;
NestWhile[Function[# /. {tail_, head_} :> (i++; tail)], right,
Function[# =!= {}]]; i]

Out[162]= {0.124, 15000}
``````
-
Why do you think that `SameQ` is involved here? Turning on tracing of `SameQ` does not show any calls to it: `On[SameQ];`. –  Alexey Popkov Apr 27 '11 at 3:04
`On[SameQ]` will only shows evaluations of `SameQ` symbol. `ReplaceRepeated` does not call the evaluator for efficiency when determining that `ReplaceRepeated` should terminate. –  Sasha Apr 27 '11 at 3:09
@Alexey No, all user provided code is executed through the evaluator. This is how the language interpreter works. –  Sasha Apr 27 '11 at 4:12
@Mr.Wizard I have given one possibility to speed up the code in my edit to the answer. –  Sasha Apr 27 '11 at 4:13
You can get the same performance as the "left" case if you use standard evaluation instead of "ReplaceRepeated": `loop@{t_,h_}:=(i++;loop@t);Block[{\$RecursionLimit=Infinity},Timing[i=0;loop@rig‌​ht;i]]` –  WReach Apr 27 '11 at 18:04