`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}}
```

versus

```
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.

`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).`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.`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.2more comments