# How to extract values from List<T> into M x 1 double[,] array concisely with less line of code?

Is it possible to extract values from a `List<T>` into a M x 1 double[,] array concisely will less lines of codes?

I have a type defined as:

``````public class Trajectory
{
public Vector3 Position { get; set; }
// ... more codes
}
``````

And Vector3 is defined as :

``````    public struct Vector3
{
public float X;
public float Y;
public float Z;

public Vector3(float x, float y, float z)
{
X = x;
Y = y;
Z = z;
}
// ... more vector3 operators
}
``````

At the moment I have `List<Trajectory> trajectory`. It has 80 entries max. I'd like to store only the X, Y, X values of each entry in `trajectory` as 240 x 1 `double[,]` array (in the order of X, then Y, then Z values).

My current solution is rather long-winding and ugly. Here it goes:

``````            // take a snapshot of current trajectory
List<Entry> tempEntry = new List<Entry> (Entries);

// create a temporary vector3Values
List<Vector3> vector3Values = new List<Vector3>();

foreach (Entry e in tempEntry)
{
}

/* Start an index at 0.
* This is for foreach iteration to extract the value of x, y, and z from each vector3
*/
int index = 0;

// find the size of the list, in case max limit is changed
int listCount = inputVector3.Count;

/* set the length of the new array by multiplying the size of the list by 3.
* We want:
* [x1 x2 x3...xn y1 y2 y3...yn z1 z2 z3...zn]'.
* Therefore, the size of the reshaped array is three times of the original array             *
*/
int maxRowLength = listCount * 3;

// create double[,] variable to store the reshaped data, three times the length of the actual list.
double[,] result = new double[maxRowLength, 1];

// start going for each vector, then store the x components in the double[,] array.
foreach (Vector3 vector3 in inputVector3)
{
result[index, 0] = vector3.X;
index++;
}

/* continuing from the previous index value, start going for each vector,
* then store the z components in the double[,] array.
*/
foreach (Vector3 vector3 in inputVector3)
{
result[index, 0] = vector3.Y;
index++;
}

/* continuing from the previous index value, start going for each vector,
* then store the z components in the double[,] array.
*/
foreach (Vector3 vector3 in inputVector3)
{
result[index, 0] = vector3.Z;
index++;
}
``````

At the end of the day I got what I wanted. M x 1 double[,] array. I use double[,] for interoperability with Matlab's MWArray object that I need at this moment.

So, the question is, is there a concise way to accomplish what I am doing here?

EDITED: This transformation will be needed a number of times per seconds (Thanks to Chris Sinclair for bringing up this issue), however, this is not an issue at the moment.

-
it's a `Double[,]` but the it's always `Double[n,1]` with the 2nd dimension being 0? (where `n` is the total number of `X`, `Y` and `Z` entries) –  Brad Christie Feb 27 '13 at 2:03
Now when you say "quickly/efficiently", do you want the best performance wise at runtme, or the simplest to maintain/read? –  Chris Sinclair Feb 27 '13 at 2:23

You could do something like the following to avoid looping three times:

``````var result = new double[entries.Count * 3, 1];

for (int i = 0; i < entries.Count; i++)
{
result[i, 0] = entries[i].Position.X;
result[i + entries.Count, 0] = entries[i].Position.Y;
result[i + entries.Count * 2, 0] = entries[i].Position.Z;
}
``````
-

If you want a "quick/efficient" method of doing this, avoiding the general enumeration of Linq might be considered. Though since you state you only have 80 entries max, I doubt it's an issue unless you're doing this many, many, many times per second.

At any rate, here's a single iteration using a standard for loop while also minimizing element lookup and struct copying (I hope):

``````int length = inputVector3.Count;

double[,] result = new double[length * 3, 1];

for (int i = 0; i < length; i++)
{
var vector = inputVector3[i];
result[i, 0] = vector.X;
result[i + length, 0] = vector.Y;
result[i + length * 2, 0] = vector.Z;
}

return result;
``````

I'm not positive if this is faster than the other options (mostly thinking about the math of `i + length` and `i + length * 2` portions); best to just try them out.

-
Hm... We will be doing this many, many, many times per second. –  ikel Feb 27 '13 at 3:05
@IwanKelaiah Then I'd suggest you setup some way of benchmarking performance before/after implementing any of the ideas here. It's important to accurately identify the current bottlenecks of the code and verify that this is one. –  Chris Sinclair Feb 27 '13 at 3:22
Actually, performance-wise is not crucial at this stage. I'm more concerned about my ugly and long winding code. I'll modify the question's title description for clarity. –  ikel Feb 27 '13 at 3:52
@IwanKelaiah Then it doesn't matter. Put all this logic in its own self-contained method, make it easy to read/maintain (and one that you understand how it operates), then benchmark it later when you go to discover bottlenecks. –  Chris Sinclair Feb 27 '13 at 11:25

I don't like my answer at all, but you could write a linq statement like this. I can't promise it will be faster, but it's a different approach to try:

`````` List<Vector3> vectors = new List<Vector3>();
//Select() will isolate the float value [X/Y/Z] of each type from the collection
//Concat() will merge the selected float[]'s to make
//  one large array containing [x1,x2,x3...y1,y2,y3...z1,z2,z3...]
float[] values = vectors.Select(e => e.X)
.Concat(vectors.Select(e => e.Y)
.Concat(vectors.Select(e => e.Z))).ToArray();
for (int i = 0; i < values.Length; i++)
{
result[i, 0] = values[i];
}
``````
-

It sounds like the LINQ command SelectMany is exactly what you're looking for.

Given List trajectory, here's what I would do:

``````double[] result = trajectory.SelectMany(t => new double[] { t.Position.X, t.Position.Y, t.Position.Z }).ToArray();
``````

What this says is: from the list of Trajectories, make an array out of the X Y and Z, and then join them all together into a big array. I've verified that this preserves order, but I don't know if this improves performance.

-
I believe the resulting array should contain [x1, x2, y1, y2, z1, z2] rather than [x1, y1, z1, x2, y2, z2]. –  Brandon Gano Feb 27 '13 at 2:26
Yeah, my answer was going to be this until I realized he needed [x1, x2, y1, y2, z1, z2], which is why I did it the way I did in my answer. –  Corylulu Feb 27 '13 at 2:28
@Lily I'd be happy to reduce my multi-line solution to one. However, as Brandon Gano pointed out, my result should be [x1,y1,z1,x2,y2,z2]. –  ikel Feb 27 '13 at 4:05
Ah, my mistake. If you are looking for [x1, x2, x3..., y1, y2, y3...] then I wholeheartedly support Corylulu's solution. Mine gives [x1, y1, z1, x2, y2, z2...] –  Lily Feb 28 '13 at 2:35