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I have been mostly a Table functions user in mathematica. However I have noticed that in several examples where I used Array instead of Table to express the same result, it ran markedly faster, especially as the dimension of table grew larger.

So my question is this: When speed of execution is the primary concern, when is it most appropriate to use table?

What explains this difference?

My guess is that because Arrays assume a functional relationship between the items in the list, it stores them more efficiently, therefore use less memory, thus facilitating storage and subsequent processing?

Is it what is going on?

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@Leonid @Sasha I'd like to add a related question here, if Phil doesn't mind. Is the only reason to choose ConstantArray over Array or Table just speed of execution? Ever since the introduction of ConstantArray I have been wondering about its purpose. I mean, it even doesn't save you typing. ConstantArray[1, 10^7] is longer than Table[1, {10^7}] and filling a table is so speedy that the difference (which when given as a factor is considerable) isn't really interesting. At least not for symbols (factor of 2), and integers (10). However, for complexes it gets interesting (50). –  Sjoerd C. de Vries Apr 23 '11 at 18:23
@belisarius I meant to say. <beat by the 5 min limit> –  Sjoerd C. de Vries Apr 23 '11 at 18:29
@Sjoerd Apart from the speed-up, the result of ConstantArray is automatically packed for numerical constants. And for numerical constants, chances are that you want it packed, so you have to add the time to pack the result produced otherwise (by Table or Array), plus the convenience - with ConstantArray you don't have to think about it. –  Leonid Shifrin Apr 23 '11 at 19:42
@Leonid Thanks, didn't know that. –  Sjoerd C. de Vries Apr 23 '11 at 19:58
@Sjoerd I must add that Array and Table (the latter in 1D only) will pack for functions which can be compiled, and for number of elements larger than corresponding settings in SystemOptions->"CompileOptions" ("ArrayCompileLength" and "TableCompileLength"). So, the difference in packing is for small lists mostly, unless the above options are reset to larger values. But, IMO, it still adds some convenience, and also it looks a bit unnatural to convert a number into a constant pure function like in Array[1&,{100}], just to fit the syntax of Array which expects a function. –  Leonid Shifrin Apr 23 '11 at 23:27

5 Answers 5

up vote 9 down vote accepted

Array has no performance advantages over Table. There are differences between them which make one preferred over another.

EDIT It was noted by several persons that Table is slower on multi-dimensional arrays. All of them used variable to hold the table size. Table has HoldAll attributes and only auto-evaluates outer-most interation bound. Because internal iterators remain unevaluated, the element of the table fails to compile. Using explicit numbers or With with result in auto-compilation:

In[2]:= With[{b = 10^4, c = 10^4},
 {Timing@(#[[1, 1]] &[ar = Array[(# + #2) &, {b, c}]]) , 
  Timing@(#[[1, 1]] &[ta = Table[(i + j), {i, b}, {j, c}]])}

Out[2]= {{4.93, 2}, {4.742, 2}}

In[3]:= Attributes[Table]

Out[3]= {HoldAll, Protected}

The Array allows you to build an array of function values just as much as the Table. They take different arguments. Array takes a function:

In[34]:= Array[Function[{i, j}, a[i, j]], {3, 3}]

Out[34]= {{a[1, 1], a[1, 2], a[1, 3]}, {a[2, 1], a[2, 2], 
  a[2, 3]}, {a[3, 1], a[3, 2], a[3, 3]}}

while table takes an explicit form:

In[35]:= Table[a[i, j], {i, 3}, {j, 3}]

Out[35]= {{a[1, 1], a[1, 2], a[1, 3]}, {a[2, 1], a[2, 2], 
  a[2, 3]}, {a[3, 1], a[3, 2], a[3, 3]}}

Array can only go over regular arrays, while Table can do arbitrary iterating over list:

In[36]:= Table[a[i, j], {i, {2, 3, 5, 7, 11}}, {j, {13, 17, 19}}]

Out[36]= {{a[2, 13], a[2, 17], a[2, 19]}, {a[3, 13], a[3, 17], 
  a[3, 19]}, {a[5, 13], a[5, 17], a[5, 19]}, {a[7, 13], a[7, 17], 
  a[7, 19]}, {a[11, 13], a[11, 17], a[11, 19]}}

Sometimes Array can be more succinct. Compare multiplication table:

In[37]:= Array[Times, {5, 5}]

Out[37]= {{1, 2, 3, 4, 5}, {2, 4, 6, 8, 10}, {3, 6, 9, 12, 15}, {4, 8,
   12, 16, 20}, {5, 10, 15, 20, 25}}


In[38]:= Table[i j, {i, 5}, {j, 5}]

Out[38]= {{1, 2, 3, 4, 5}, {2, 4, 6, 8, 10}, {3, 6, 9, 12, 15}, {4, 8,
   12, 16, 20}, {5, 10, 15, 20, 25}}

Array allows one to build expression with any head, not just list:

In[39]:= Array[a, {3, 3}, {1, 1}, h]

Out[39]= h[h[a[1, 1], a[1, 2], a[1, 3]], h[a[2, 1], a[2, 2], a[2, 3]],
  h[a[3, 1], a[3, 2], a[3, 3]]]

By default the head h is chosen to be List resulting in creation of the regular array. Table does not have this flexibility.

share|improve this answer
@Phil I have also expanded the answer. The performance will be better when you get to the result in smaller amount of evaluations. See stackoverflow.com/questions/4721171/… –  Sasha Apr 23 '11 at 15:05
There are cases where Array is significantly faster, particularly for multi-dimensional arrays. Consider, for instance, b = 1000; c = 1000; Timing@(#[[1, 1]] &[ar = Array[(# + #2) &, {b, c}]]) Timing@(#[[1, 1]] &[ta = Table[(i + j), {i, b}, {j, c}]]). So the statement of speed equivalence seems to hold only for linear arrays. Perhaps, for multi-dimensional arrays Table can not fully utilize the auto-compilation (perhaps can not ensure that array is indeed rectangular, thus can not pack) - I have no other explanation for an order of magnitude performance difference of the above example. –  Leonid Shifrin Apr 23 '11 at 16:27
@Leonid In your example the array produced by Array is packed array while for Table is not: Developer`PackedArrayQ /@ {ar, ta} gives {True, False}. –  Alexey Popkov Apr 23 '11 at 22:07
@Alexey That's exactly the point. Array can often pack, since the resulting array is known to be rectangular. For Table, this is not always true, since iterators may be dependent on other iterators. See also my comment to @Sjoerd's question on ConstantArray. –  Leonid Shifrin Apr 23 '11 at 22:39
@Leonid Please see an edit to my answer, which explains why Table was not performing equally with Array in your comment from yesterday. –  Sasha Apr 25 '11 at 15:01

Michael Trott in Programming (pp 707 - 710) address the issue of the differences between Array and Table and argues that as Table has the attribute HoldAll it computes its argument for every call, whereas Array "to the extent possible" computes its argument only at the beginning. This may lead to differences in behaviour as well as speed.


{HoldAll, Protected}



Michael Trott uses the following examples to illustrate the difference in both speed and behaviour. I am taking them verbatim from his book (disc). I hope I am not breaking any rules by doing so.

Remove[a, i, j];
a = 0;
Table[a = a + 1; ToExpression[StringJoin["a" <> ToString[a]]][i, j],
       {i, 3}, {j, 3}]

{{a1[1, 1], a2[1, 2], a3[1, 3]}, {a4[2, 1], a5[2, 2], a6[2, 3]}, {a7[3, 1], a8[3, 2], a9[3, 3]}}

a = 0;
Array[a = a + 1; 
 ToExpression[StringJoin["a" <> ToString[a]]], {3, 3}] 

{{a1[1, 1], a1[1, 2], a1[1, 3]}, {a1[2, 1], a1[2, 2], a1[2, 3]}, {a1[3, 1], a1[3, 2], a1[3, 3]}}

(Note the difference in behaviour)

To illustrate the effect of precomputing the first argument he uses the following example (again verbatim, p 709).

o[a = 0;
  Table[a = a + 1; 
   ToExpression[StringJoin["a" <> ToString[a]]][i, j],
         {i, 3}, {j, 3}], {2000}] // Timing
Do[a = 0;
  Array[a = a + 1; ToExpression[ StringJoin["a" <> ToString[a]]], 
                                            {3, 3}], {2000}] // Timing

{0.700173, Null}

{0.102587, Null}

(I am using mma7 on a Mac. My copy of Programming uses v5.1. There may well be an update to this)

This is not the only difference between Array and Table discussed in Programming, of course.

I view of other answers, I'll be interested to learn what others think of this point.

share|improve this answer

One reason Array may be faster is that it often compiles its first argument better.

In Mathematica 7:

In[1]:= SystemOptions[CompileOptions -> ArrayCompileLength]

Out[1]= {"CompileOptions" -> {"ArrayCompileLength" -> 250}}


In[2]:= SystemOptions[CompileOptions -> TableCompileLength]

Out[2]= {"CompileOptions" -> {"TableCompileLength" -> 250}}

So one can infer that Array and Table should compile at the same point.

But let's try it. I will be making use of Timo's timeAvg function:

n = 15;
Array[Mod[#^2, 5]*(1 + #2) &, {n, n}] // timeAvg
Table[Mod[i^2, 5]*(1 + j), {i, n}, {j, n}] // timeAvg

(* Out = 0.00034496 *)

(* Out = 0.00030016 *)

n = 16;
Array[Mod[#^2, 5]*(1 + #2) &, {n, n}] // timeAvg
Table[Mod[i^2, 5]*(1 + j), {i, n}, {j, n}] // timeAvg

(* Out = 0.000060032 *)

(* Out = 0.0005008   *)

What we see is that Array is able to compile Mod[#^2, 5]*(1 + #2) & while Table is not able to compile Mod[i^2, 5]*(1 + j) and therefore for Array becomes faster when the CompileLength is reached. Many functions are not so favorable. If you merely change multiplication to division in the function, which results in a rational rather than integer result, then this auto-compile does not happen, and Table is faster:

n = 15;
Array[Mod[#^2, 5]/(1 + #2) &, {n, n}] // timeAvg
Table[Mod[i^2, 5]/(1 + j), {i, n}, {j, n}] // timeAvg

(* Out = 0.000576   *)

(* Out = 0.00042496 *)

n = 16;
Array[Mod[#^2, 5]/(1 + #2) &, {n, n}] // timeAvg
Table[Mod[i^2, 5]/(1 + j), {i, n}, {j, n}] // timeAvg

(* Out = 0.0005744  *)

(* Out = 0.0004352  *)

But what if we can make this compile too? If we use floating point numbers, done by starting with 1., we get Real output, which can be compiled:

n = 15;
Array[Mod[#^2, 5]/(1 + #2) &, {n, n}, 1.] // timeAvg
Table[Mod[i^2, 5]/(1 + j), {i, 1., n}, {j, 1., n}] // timeAvg

(* Out = 0.0006256  *)

(* Out = 0.00047488 *)

n = 16;
Array[Mod[#^2, 5]/(1 + #2) &, {n, n}, 1.] // timeAvg
Table[Mod[i^2, 5]/(1 + j), {i, 1., n}, {j, 1., n}] // timeAvg

(* Out = 0.00010528 *)

(* Out = 0.00053472 *)

And once again, Array is faster on the larger dimension array.

share|improve this answer
+1 for the expanded analysis of autocompilation. As for why Table is slower for multi-dimensional arrays, I think it is not because Table is unable to compile, but because it is unable to determine that the resulting array is rectangular (since you can create non-rectangular nested lists with Table), and thus can not pack - as I mentioned in my first comment to @Sasha's answer. And if you don't pack, there is little advantage in using Compile, assuming that your function is not incredibly computationally demanding on a single number. But this is just a guess, I don't know for sure. –  Leonid Shifrin Apr 24 '11 at 14:08

Your statement:

However I have noticed that in several examples where I used Array instead of Table to express the same result, it ran markedly faster, especially as the dimension of table grew larger.

is not usually true for one-dimensional arrays. Take a look:

$HistoryLength = 0;
a = 10^8;
arr = {}; tab = {};
   arr = {First@Timing@Array[# &, a], arr};
   tab = {First@Timing@Table[i, {i, a}], tab};
   ), {10}];

ListLinePlot[{Flatten@arr, Flatten@tab}, 
 AxesLabel -> {Style["Iteration", 14], Style["Time", 14]}, 
 PlotLegend -> {Style["Array", 14], Style["Table", 14]}, 
 PlotRange -> {{0, 10}, {1.6, 2}}]  

enter image description here

share|improve this answer
@belisarius For higher-dimensional arrays, there are cases when Array is order of magnitude faster than Table, see my comment to @Sasha's answer for an example. –  Leonid Shifrin Apr 23 '11 at 17:22
@Leonid Thanks. Added that. –  belisarius Apr 23 '11 at 17:46
+1 but dropshadows for legends are ugly... –  Sjoerd C. de Vries Apr 23 '11 at 17:57
@Sjoerd You can control them with ShadowOffset –  belisarius Apr 23 '11 at 18:05
@ belisarius:I made that observation myself in my comment to @sasha above. @leonid then pointed that in higher dimensions, array has the edge over table...Indeed I made this observation based on work when handling tensors of dim>1 . Liked the plot! –  Phil Apr 23 '11 at 18:14

Without giving some conrete examples, it is difficult to answer your question correctly.

Since Mathematica is a closed source program, the exact implementations behind Table and Array cannot be known, unless explained by people that were involved in development of Mathematica.

These factors will hinder your ability to reason which structure you should use in what circumstances. Experimentation will be your best bet, so I would suggest you keep parallel versions of your programs, one using Table, one using Array. This way, you'll be able to see which one is faster.

Even better, you could write a wrapper function which depends on a global variable. This function will, depending on the variable, use Table, or Array as the underlying implementation, so you will be able to quickly switch from one version to another, without doing many modifications to your code.

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thanks. I am looking for structural explanations, so numerical examples won't provide the insights I am looking for.I have edited the question to make it clearer. –  Phil Apr 23 '11 at 15:01

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