Often we need to process data consisting of a list of coordinates: `data = {{x1,y1}, {x2,y2}, ..., {xn,yn}}`

. It could be 2D or 3D coordinates, or any other arbitrary length list of fixed length small vectors.

Let me illustrate how to use `Compile`

for such problems using the simple example of summing up a list of 2D vectors:

```
data = RandomReal[1, {1000000, 2}];
```

First, obvious version:

```
fun1 = Compile[{{vec, _Real, 2}},
Module[{sum = vec[[1]]},
Do[sum += vec[[i]], {i, 2, Length[vec]}];
sum
]
]
```

How fast is it?

```
In[13]:= Do[fun1[data], {10}] // Timing
Out[13]= {4.812, Null}
```

Second, less obvious version:

```
fun2 = Compile[{{vec, _Real, 1}},
Module[{sum = vec[[1]]},
Do[sum += vec[[i]], {i, 2, Length[vec]}];
sum
]
]
In[18]:= Do[
fun2 /@ Transpose[data],
{10}
] // Timing
Out[18]= {1.078, Null}
```

As you can see, the second version is much faster. Why? Because the crucial operation, `sum += ...`

is an addition of numbers in `fun2`

while it's an addition of *arbitrary length* vectors in `fun1`

.

You can see a practical application of the same "optimization" in this asnwer of mine, but many other examples could be given where this is relevant.

Now in this simple example the code using `fun2`

is not longer or much more complex than `fun1`

, but in the general case it very well might be.

**How can I tell Compile that one of its arguments is not an arbitrary n*m matrix, but a special n*2 or n*3 one, so it can do these optimization automatically rather than using a generic vector addition function to add tiny length-2 or length-3 vectors?**

## Addendum

To make it more clear what's happening, we can use `CompilePrint`

:

`CompilePrint[fun1]`

gives

```
1 argument
5 Integer registers
5 Tensor registers
Underflow checking off
Overflow checking off
Integer overflow checking on
RuntimeAttributes -> {}
T(R2)0 = A1
I1 = 2
I0 = 1
Result = T(R1)3
1 T(R1)3 = Part[ T(R2)0, I0]
2 I3 = Length[ T(R2)0]
3 I4 = I0
4 goto 8
5 T(R1)2 = Part[ T(R2)0, I4]
6 T(R1)4 = T(R1)3 + T(R1)2
7 T(R1)3 = CopyTensor[ T(R1)4]]
8 if[ ++ I4 < I3] goto 5
9 Return
```

`CompilePrint[fun2]`

gives

```
1 argument
5 Integer registers
4 Real registers
1 Tensor register
Underflow checking off
Overflow checking off
Integer overflow checking on
RuntimeAttributes -> {}
T(R1)0 = A1
I1 = 2
I0 = 1
Result = R2
1 R2 = Part[ T(R1)0, I0]
2 I3 = Length[ T(R1)0]
3 I4 = I0
4 goto 8
5 R1 = Part[ T(R1)0, I4]
6 R3 = R2 + R1
7 R2 = R3
8 if[ ++ I4 < I3] goto 5
9 Return
```

I chose to include this rather than the considerably lengthier C version, where the timing difference is even more pronounced.