I am producing flat lists with 10^6 to 10^7 Real numbers, and some of them are repeating.

I need to delete the repeating instances, keeping the first occurrence only, and without modifying the list order.

The key here is efficiency, as I have a lot of lists to process.

Example (fake):


  {.8, .3 , .8, .5, .3, .6}

Desired Output

  {.8, .3, .5, .6}  

Aside note

Deleting repeating elements with Union (without preserving order) gives in my poor man's laptop:

DiscretePlot[a = RandomReal[10, i]; First@Timing@Union@a, {i, 10^6 Range@10}]

enter image description here

3 Answers 3


You want DeleteDuplicates, which preserves list order:

In[13]:= DeleteDuplicates[{.8, .3, .8, .5, .3, .6}]

Out[13]= {0.8, 0.3, 0.5, 0.6}

It was added in Mathematica 7.0.

  • 4
    @Michael: I'd rather use DeleteDuplicates[...,Equal], given that the numbers in question are real, and default comparison is SameQ. Much slower, but more robust. Mar 9, 2011 at 13:59
  • hmm, I always forget about the built-ins like DeleteDuplicates. For what its worth, as a built-in in runs 3 - 6 times faster across ~10^6 elements than unsortedUnion in my answer. (Note, this is using SameQ not Equal.)
    – rcollyer
    Mar 9, 2011 at 15:06
  • @Leonid would it work to Round the numbers first, to something just less than $MachinePrecision and use plain DeleteDuplicates since DeleteDuplicates[...,Equal] is so very slow, and belisarius wants speed?
    – Mr.Wizard
    Mar 9, 2011 at 15:28
  • 1
    @Mr.Wizard: This might work, but not sure if what you propose is robust enough, I wouldn't rely on SameQ in general for numerics. But, as @belisarius notes, for his purposes SameQ seems fine. @belisarius Ok, then DeleteDuplicates is your friend indeed. Another (robust but slower) alternative is Tally[list, Equal][[All, 1]]. Regarding Union being slow with explicit test, this is mainly because it switches to quadratic-time algorithm, see this thread for instance: groups.google.com/group/comp.soft-sys.math.mathematica/… Mar 9, 2011 at 15:59
  • 1
    @belisarius, just checked timing on Union and it runs about twice as fast as this code. So, much for the utility of my solution. Removed it, as it cannot compete.
    – rcollyer
    Mar 9, 2011 at 16:19

Not to compete with other answers, but I just could not help sharing a Compile - based solution. The solution is based on building a binary search tree, and then checking for every number in the list, whether its index in the list is the one used in building the b-tree. If yes, it is the original number, if no - it is a duplicate. What makes this solution interesting for me is that it shows a way to emulate "pass-by-reference" with Compile. The point is that, if we inline compiled functions into other Compiled functions (and that can be achieved with an "InlineCompiledFunctions" option), we can refer in inner functions to the variables defined in outer function scope (because of the way inlining works). This is not a true pass-by-reference, but it still allows to combine functions from smaller blocks, without efficiency penalty (this is more in the spirit of macro-expnsion). I don't think this is documented, and have no idea whether this will stay in future versions. Anyways, here is the code:

(* A function to build a binary tree *)
Block[{leftchildren , rightchildren},
makeBSearchTree = 
Compile[{{lst, _Real, 1}},
Module[{len = Length[lst], ctr = 1, currentRoot = 1},
 leftchildren = rightchildren =  Table[0, {Length[lst]}];
 For[ctr = 1, ctr <= len, ctr++,
  For[currentRoot = 1, lst[[ctr]] != lst[[currentRoot]],(* 
   nothing *),
   If[lst[[ctr]] < lst[[currentRoot]],
    If[leftchildren[[currentRoot]] == 0,
     leftchildren[[currentRoot]] = ctr;
     (* else *)
     currentRoot = leftchildren[[currentRoot]] ],
    (* else *)
    If[rightchildren[[currentRoot]] == 0,
     rightchildren[[currentRoot]] = ctr;
     (* else *)
     currentRoot = rightchildren[[currentRoot]]]]]];
 ], {{leftchildren, _Integer, 1}, {rightchildren, _Integer, 1}},
CompilationTarget -> "C", "RuntimeOptions" -> "Speed",
CompilationOptions -> {"ExpressionOptimization" -> True}]];

(* A function to query the binary tree and check for a duplicate *)
Block[{leftchildren , rightchildren, lst},
isDuplicate = 
Compile[{{index, _Integer}},
Module[{currentRoot = 1, result = True},
   lst[[index]] == lst[[currentRoot]],
    result = index != currentRoot;
   lst[[index]] < lst[[currentRoot]],
    currentRoot = leftchildren[[currentRoot]],
    currentRoot = rightchildren[[currentRoot]]
{{leftchildren, _Integer, 1}, {rightchildren, _Integer, 
  1}, {lst, _Real, 1}},
CompilationTarget -> "C", "RuntimeOptions" -> "Speed",
CompilationOptions -> {"ExpressionOptimization" -> True}

(* The main function *)
deldup = 
Compile[{{lst, _Real, 1}},
  Module[{len = Length[lst], leftchildren , rightchildren , 
     nodup = Table[0., {Length[lst]}], ndctr = 0, ctr = 1},
For[ctr = 1, ctr <= len, ctr++,
 If[! isDuplicate [ctr],
   nodup[[ndctr]] =  lst[[ctr]]
Take[nodup, ndctr]], CompilationTarget -> "C", 
"RuntimeOptions" -> "Speed",
CompilationOptions -> {"ExpressionOptimization" -> True,
 "InlineCompiledFunctions" -> True, 
 "InlineExternalDefinitions" -> True}];

Here are some tests:

In[61]:= intTst = N@RandomInteger[{0,500000},1000000];

In[62]:= (res1 = deldup[intTst ])//Short//Timing
Out[62]= {1.141,{260172.,421188.,487754.,259397.,<<432546>>,154340.,295707.,197588.,119996.}}

In[63]:= (res2 = Tally[intTst,Equal][[All,1]])//Short//Timing
Out[63]= {0.64,{260172.,421188.,487754.,259397.,<<432546>>,154340.,295707.,197588.,119996.}}

In[64]:= res1==res2
Out[64]= True

Not as fast as the Tally version, but also Equal - based, and as I said, my point was to illustrate an interesting (IMO) technique.

  • I don't understand half of what you wrote, so I'll have to trust you know what you're doing, but it sounds cool, so +1. Some day I am going to have to learn a lower level language, and then maybe I'll understand.
    – Mr.Wizard
    Mar 9, 2011 at 20:31
  • @Leonid +1 Thanks for sharing these ideas. I'm sure I'll learn a quite a few things Mar 10, 2011 at 0:03
  • 1
    @Leonid This is an interesting technique and somewhat unconventional use of Compile. The performance if your compiled code is hampered by calls back to Mathematica from compiled code. You can see them by loading Needs["CompiledFunctionTools"] (n.b.: use backtick), and evaluating CompilePrint[makeBSearchTree]. You will see occurrences of MainEvaluate meaning a call back to Mathematica.
    – Sasha
    Apr 22, 2011 at 15:38
  • 1
    @Sasha: At first, I got confused by your observation. But then, I looked at the final code of deldup (through CompilePrint), and found exactly what I was hoping for (i.e. what I expected intuitively from my limited experiences with this technique): the compiler is smart enough to remove the calls to MainEvaluate from the functions being inlined into another Compiled function! So, If there is inefficiency here, it is not due to the calls to mma evaluator, I think. The status of auxiliary functions is that of building blocks, they are not supposed to be used on their own. Apr 22, 2011 at 17:28
  • 1
    @Leonid Yes, you are right! In that case one can drop CompilationTarget->"C" in those auxiliary functions. Compile will be using only their Mathematica representation when building deldup. From the look at compiled print the code is as efficient as it gets, so I think Tally simply uses more efficient algorithm, coupled with better optimized code, I guess.
    – Sasha
    Apr 22, 2011 at 17:39

For versions of Mathematica before 7, and for general interest, here are several ways of implementing the UnsortedUnion (i.e. DeleteDuplicates) function. These are collected from the help docs and MathGroup. They have been adjusted to accept multiple lists which are then joined, in analogy to Union.

For Mathematica 4 or earlier

UnsortedUnion = Module[{f}, f[y_] := (f[y] = Sequence[]; y); f /@ Join@##] &

For Mathematica 5

UnsortedUnion[x__List] := Reap[Sow[1, Join@x], _, # &][[2]]

For Mathematica 6

UnsortedUnion[x__List] := Tally[Join@x][[All, 1]]

From Leonid Shifrin for Mathematica 3+ (?)

unsortedUnion[x_List] := Extract[x, Sort[Union[x] /. Dispatch[MapIndexed[Rule, x]]]]
  • 1
    @Mr. And the is no "archeologist badge" here! +1 Mar 9, 2011 at 18:57
  • Although it probably dosen't matter too much, Ted Ersek points out that the UnsortedUnion Version 1 will fail with lists such as {3, 1, 1, f[3], 3, 2, f[3], 1, 1, 8, 2, 6, 8}. (He discusses the origin of this function, {due originally to Carl Woll?} here, under 'Clever Little Programs' His Version: ClearAll[DeleteRepititions]; DeleteRepititions[x_]:= Module[{t}, t[n_]:= (t[n] = Sequence[]; n); t/@x])
    – 681234
    Mar 10, 2011 at 13:54
  • @TomD Well caught. Block changed to Module
    – Mr.Wizard
    Mar 10, 2011 at 14:13
  • 2
    @Mr.Wizard Here is another one to add to your collection :) : unsortedUnion[x_List] := Extract[x, Sort[Union[x] /. Dispatch[MapIndexed[Rule, x]]]]. Works since I think v.4.2 (when Dispatch was introduced). For large lists, about 2-3 times faster than the Reap-Sow version. I discuss it in my book here: mathprogramming-intro.org/book/node479.html Mar 10, 2011 at 14:54
  • @Leonid Thanks. I have not read that section yet. I am sure I will learn a lot before I finish your book. Then I shall await version 2.
    – Mr.Wizard
    Mar 10, 2011 at 15:20

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

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