Suppose we want to generate a list of primes p for which p + 2 is also prime.

A quick solution is to generate a complete list of the first n primes and use the Select function to return the elements which meet the condition.

Select[Table[Prime[k], {k, n}], PrimeQ[# + 2] &]

However, this is inefficient as it loads a large list into the memory before returning the filtered list. A For loop with Sow/Reap (or l = {}; AppendTo[l, k]) solves the memory issue, but it is far from elegant and is cumbersome to implement a number of times in a Mathematica script.

  For[k = 1, k <= n, k++,
   p = Prime[k];
   If[PrimeQ[p + 2], Sow[p]]
 ][[-1, 1]]

An ideal solution would be a built-in function which allows an option similar to this.

Table[Prime[k], {k, n}, AddIf -> PrimeQ[# + 2] &]
  • so essentially you want a more sophisticated list comprehension...
    – Simon
    Jun 16, 2011 at 7:17
  • 3
    by the way: there's a simple twin primes generator using Select in the NextPrime documentation.
    – Simon
    Jun 16, 2011 at 7:19
  • Nice find, I didn't catch that. Of course, finding twin primes was just an easy example I could think of for this.
    – Vortico
    Jun 17, 2011 at 3:57
  • Related: stackoverflow.com/q/6313505/618728
    – Mr.Wizard
    Jan 16, 2012 at 10:20

6 Answers 6


I will interpret this more as a question about automation and software engineering rather than about the specific problem at hand, and given a large number of solutions posted already. Reap and Sow are good means (possibly, the best in the symbolic setting) to collect intermediate results. Let us just make it general, to avoid code duplication.

What we need is to write a higher-order function. I will not do anything radically new, but will simply package your solution to make it more generally applicable:

tableGen[f_, iter : {i_Symbol, __}, addif : Except[_List] : (True &)] :=
  If[# === {}, #, First@#] &@
       Last@Reap[Do[If[addif[#], Sow[#,sowTag]] &[f[i]], iter],sowTag]];

The advantages of using Do over For are that the loop variable is localized dynamically (so, no global modifications for it outside the scope of Do), and also the iterator syntax of Do is closer to that of Table (Do is also slightly faster).

Now, here is the usage

In[56]:= tableGen[Prime, {i, 10}, PrimeQ[# + 2] &]

Out[56]= {3, 5, 11, 17, 29}

In[57]:= tableGen[Prime, {i, 3, 10}, PrimeQ[# + 1] &]

Out[57]= {}

In[58]:= tableGen[Prime, {i, 10}]

Out[58]= {2, 3, 5, 7, 11, 13, 17, 19, 23, 29}


This version is closer to the syntax you mentioned (it takes an expression rather than a function):

SetAttributes[tableGenAlt, HoldAll];
tableGenAlt[expr_, iter_List, addif : Except[_List] : (True &)] :=
  If[# === {}, #, First@#] &@
    Last@Reap[Do[If[addif[#], Sow[#,sowTag]] &[expr], iter],sowTag]];

It has an added advantage that you may even have iterator symbols defined globally, since they are passed unevaluated and dynamically localized. Examples of use:

In[65]:= tableGenAlt[Prime[i], {i, 10}, PrimeQ[# + 2] &]

Out[65]= {3, 5, 11, 17, 29}

In[68]:= tableGenAlt[Prime[i], {i, 10}]

Out[68]= {2, 3, 5, 7, 11, 13, 17, 19, 23, 29}

Note that since the syntax is different now, we had to use the Hold-attribute to prevent the passed expression expr from premature evaluation.


Per @Simon's request, here is the generalization for many dimensions:

SetAttributes[tableGenAltMD, HoldAll];
tableGenAltMD[expr_, iter__List, addif : Except[_List] : (True &)] :=
Module[{indices, indexedRes, sowTag},
  SetDelayed @@  Prepend[Thread[Map[Take[#, 1] &, List @@ Hold @@@ Hold[iter]], 
      Hold], indices];
  indexedRes = 
    If[# === {}, #, First@#] &@
      Last@Reap[Do[If[addif[#], Sow[{#, indices},sowTag]] &[expr], iter],sowTag];
    SplitBy[indexedRes , 
      Table[With[{i = i}, Function[Slot[1][[2, i]]]], {i,Length[Hold[iter]] - 1}]], 

It is considerably less trivial, since I had to Sow the indices together with the added values, and then split the resulting flat list according to the indices. Here is an example of use:

{i, j, k} = {1, 2, 3};
tableGenAltMD[i + j + k, {i, 1, 5}, {j, 1, 3}, {k, 1, 2}, # < 7 &]

{{{3, 4}, {4, 5}, {5, 6}}, {{4, 5}, {5, 6}, {6}}, {{5, 6}, {6}}, {{6}}}

I assigned the values to i,j,k iterator variables to illustrate that this function does localize the iterator variables and is insensitive to possible global values for them. To check the result, we may use Table and then delete the elements not satisfying the condition:

DeleteCases[Table[i + j + k, {i, 1, 5}, {j, 1, 3}, {k, 1, 2}], 
    x_Integer /; x >= 7, Infinity] //. {} :> Sequence[]

Out[126]= {{{3, 4}, {4, 5}, {5, 6}}, {{4, 5}, {5, 6}, {6}}, {{5, 6}, {6}}, {{6}}}

Note that I did not do extensive checks so the current version may contain bugs and needs some more testing.


Note the important bug-fix: in all functions, I now use Sow with a custom unique tag, and Reap as well. Without this change, the functions would not work properly when expression they evaluate also uses Sow. This is a general situation with Reap-Sow, and resembles that for exceptions (Throw-Catch).

EDIT 4 - SyntaxInformation

Since this is such a potentially useful function, it is nice to make it behave more like a built-in function. First we add syntax highlighting and basic argument checking through

SyntaxInformation[tableGenAltMD] = {"ArgumentsPattern" -> {_, {_, _, _., _.}.., _.},
                                    "LocalVariables" -> {"Table", {2, -2}}};

Then, adding a usage message allows the menu item "Make Template" (Shift+Ctrl+k) to work:

tableGenAltMD::usage = "tableGenAltMD[expr,{i,imax},addif] will generate \
a list of values expr when i runs from 1 to imax, \
only including elements if addif[expr] returns true.
The default of addiff is True&."

A more complete and formatted usage message can be found in this gist.

  • +1. That's a very handy function. Is it possible to make it behave like Table for multiple iterators and output a multidimensional list? At the moment, the naive replacement of iter_ with iter__ works, but for obvious reasons, yields a flattened list.
    – Simon
    Jun 16, 2011 at 9:00
  • @Simon I added a multi-dimensional version, see my edit. It is however considerably more complex / obscure and perhaps less elegant. Jun 16, 2011 at 9:39
  • @Leonid: Ouch! A lot less elegant. It looks like the type of code you only understand as you're writing it. I understand how it works (thanks to your description), but still... Although it's a lot more complicated than your other solution, the speed hit is not too bad.
    – Simon
    Jun 16, 2011 at 10:39
  • @Leonid: btw, tableGen[i + j, {i, 2}, {j, 2}] doesn't work since it thinks {j,2} is the addif function. To make it work you need to restrict the head of addif or perform some other pattern check.
    – Simon
    Jun 16, 2011 at 10:42
  • 1
    @Vortico: I doubt you added it to your Mma kernel (unless you work at WRI?) - but I agree, it is a function that I can see myself using quite regularly. Thanks again Leonid!
    – Simon
    Jun 17, 2011 at 6:46

I think the Reap/Sow approach is likely to be most efficient in terms of memory usage. Some alternatives might be:

DeleteCases[(With[{p=Prime[#]},If[PrimeQ[p+2],p,{}] ] ) & /@ Range[K]),_List]

Or (this one might need some sort of DeleteCases to eliminate Null results):

FoldList[[(With[{p=Prime[#2]},If[PrimeQ[p+2],p] ] )& ,1.,Range[2,K] ]

Both hold a big list of integers 1 to K in memory, but the Primes are scoped inside the With[] construct.


Yes, this is another answer. Another alternative that includes the flavour of the Reap/Sow approach and the FoldList approach would be to use Scan.

result = {1};
Scan[With[{p=Prime[#]},If[PrimeQ[p+2],result={result,p}]]&,Range[2,K] ];

Again, this involves a long list of integers, but the intermediate Prime results are not stored because they are in the local scope of With. Because p is a constant in the scope of the With function, you can use With rather than Module, and gain a bit of speed.

  • You can avoid using With by using a pure function to avoid double-evaluation: If[PrimeQ[# + 2], result = {result, #}] &[Prime[#]] &. This is not always possible, but possible here since the body of your If does not contain slot variables (#1 etc). Jun 16, 2011 at 10:37
  • Thanks @Leonid: these are things I just can't try out at work because (a) I don't have Mma installed there and (b) I'm meant to be working on other things. Is there a particular reason to avoid With, though?
    – Verbeia
    Jun 16, 2011 at 11:44
  • I just thought pure-function-based method is a bit simpler. Also, since With is a scoping construct and must resolve possible name conflicts, anonymous pure functions might be slightly faster. Jun 16, 2011 at 11:49
  • @Leonid: fair enough, I just don't trust my ability to write nested pure functions like that while flying blind.
    – Verbeia
    Jun 16, 2011 at 11:57
  • And this may be a right thing to do for me as well. I am not at all sure that the loss of readability in my solution is justified in the long term. Jun 16, 2011 at 12:02

You can perhaps try something like this:

Clear[f, primesList]
f = With[{p = Prime[#]},Piecewise[{{p, PrimeQ[p + 2]}}, {}] ] &;
primesList[k_] := Union@Flatten@(f /@ Range[k]);

If you want both the prime p and the prime p+2, then the solution is

Clear[f, primesList]
f = With[{p = Prime[#]},Piecewise[{{p, PrimeQ[p + 2]}}, {}] ] &;
primesList[k_] := 
  Module[{primes = f /@ Range[k]}, 
   Union@Flatten@{primes, primes + 2}];
  • 1
    You're evaluating Prime[p] twice for each case. I'd suggest changing the function f to use With[{p=Prime[#]},Piecewise... etc
    – Verbeia
    Jun 16, 2011 at 8:28
  • @Verbeia: Thanks for pointing that out, I had forgotten to do so.
    – abcd
    Jun 16, 2011 at 8:36

Well, someone has to allocate memory somewhere for the full table size, since it is not known before hand what the final size will be.

In the good old days before functional programming :), this sort of thing was solved by allocating the maximum array size, and then using a separate index to insert to it so no holes are made. Like this

x=Table[0,{100}];  (*allocate maximum possible*)
Table[ If[PrimeQ[k+2], x[[++j]]=k],{k,100}];

x[[1;;j]]  (*the result is here *)

  • 6
    I disagree with your first statement. Allocating memory for a full table is the last resort, and a waste of resources. The only reason to do that in Mathematica is when we know the upper bounds for the size and are ready to trade memory for speed (given the nature of mma performance-tuning). Generally, when the size is not known in advance, the solution is to not allocate huge memory but to construct a list dynamically. In a lower level language like C one would likely use linked lists for that. Linked lists may also be used in Mathematica, but Reap-Sow approach is superior. Jun 16, 2011 at 8:22
  • 1
    And by the way, functional programming is almost as old as imperative. LISP is just a year younger than Fortran, and older than most other languages currently in use. Jun 16, 2011 at 8:25
  • @Leonid, when I said to allocate maximum size, I am clearly talking about this problem. We know the maximum size here is N, where N=100 in this case. For such problems, I do not see how anything else can be more efficient. Access to an array is O(1) in time. nothing can be faster than that?
    – Nasser
    Jun 16, 2011 at 9:07
  • @me, After thinking more, I realized this is a prime number thing. And since prime number are very sparse, then allocating the maximum number is not wise. Unless one knows EXACTLY what the total number of primes that will be found with such property, (i.e. p+2 is also prime) I do not know prime number theory, so do not know if this is something which is known. What I mean to say is that if one knows before hand how much storage is needed, then pre-allocating an array to hold the result in is very efficient. It is a typical trade-off between time and space I suppose.
    – Nasser
    Jun 16, 2011 at 9:32
  • @Nasser At the moment it is assumed that there is an infinite number of twin primes. See en.wikipedia.org/wiki/Twin_prime
    – DavidC
    Jun 16, 2011 at 13:10

Here's another couple of alternatives using NextPrime:

pairs1[pmax_] := Select[Range[pmax], PrimeQ[#] && NextPrime[#] == 2 + # &]

pairs2[pnum_] := Module[{p}, NestList[(p = NextPrime[#];
                      While[p + 2 != (p = NextPrime[p])]; 
                      p - 2) &, 3, pnum]] 

and a modification of your Reap/Sow solution that lets you specify the maximum prime:

pairs3[pmax_] := Module[{k,p},
                   Reap[For[k = 1, (p = Prime[k]) <= pmax, k++,
                        If[PrimeQ[p + 2], Sow[p]]]][[-1, 1]]]

The above are in order of increasing speed.

In[4]:= pairs2[10000]//Last//Timing
Out[4]= {3.48,1261079}
In[5]:= pairs1[1261079]//Last//Timing
Out[5]= {6.84,1261079}
In[6]:= pairs3[1261079]//Last//Timing
Out[7]= {0.58,1261079}

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