# How do I compute the linear index of a 3D coordinate and vice versa?

If I have a point (x, y z), how do I find the linear index, i for that point? My numbering scheme would be (0,0,0) is 0, (1, 0, 0) is 1, . . ., (0, 1, 0) is the max-x-dimension, .... Also, if I have a linear coordinate, i, how do I find (x, y, z)? I can't seem to find this on google, all the results are filled with other irrelevant stuff. Thank you!

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oops, fixing it. –  user1438116 Jun 5 '12 at 19:32
Are the coordinates always composed of integers? can you have negative coordinates? Do you have maximums for any axes besides the x axis? –  Kevin Jun 5 '12 at 19:37
Does each coordinate have the same number of divisions, or different? The last point is represented by `(N,N,N)` or `(N1,N2,N3)`? –  ja72 Jun 5 '12 at 19:45

There are a few ways to map a 3d coordinate to a single number. Here's one way.

some function f(x,y,z) gives the linear index of coordinate(x,y,z). It has some constants a,b,c,d which we want to derive so we can write a useful conversion function.

``````f(x,y,z) = a*x + b*y + c*z + d
``````

You've specified that (0,0,0) maps to 0. So:

``````f(0,0,0) = a*0 + b*0 + c*0 + d = 0
d = 0
f(x,y,z) = a*x + b*y + c*z
``````

That's d solved. You've specified that (1,0,0) maps to 1. So:

``````f(1,0,0) = a*1 + b*0 + c*0 = 1
a = 1
f(x,y,z) = x + b*y + c*z
``````

That's a solved. Let's arbitrarily decide that the next highest number after (MAX_X, 0, 0) is (0,1,0).

``````f(MAX_X, 0, 0) = MAX_X
f(0, 1, 0) = 0 + b*1 + c*0 = MAX_X + 1
b = MAX_X + 1
f(x,y,z) = x + (MAX_X + 1)*y + c*z
``````

That's b solved. Let's arbitrarily decide that the next highest number after (MAX_X, MAX_Y, 0) is (1,0,0).

``````f(MAX_X, MAX_Y, 0) = MAX_X + MAX_Y * (MAX_X + 1)
f(0,0,1) = 0 + (MAX_X + 1) * 0  + c*1 = MAX_X + MAX_Y * (MAX_X + 1) + 1
c = MAX_X + MAX_Y * (MAX_X + 1) + 1
c = (MAX_X + 1) + MAX_Y * (MAX_X + 1)
c = (MAX_X + 1) * (MAX_Y + 1)
``````

now that we know a, b, c, and d, we can write your function.

``````function linearIndexFromCoordinate(x,y,z, max_x, max_y){
a = 1
b = max_x + 1
c = (max_x + 1) * (max_y + 1)
d = 0
return a*x + b*y + c*z + d
}
``````

You can get the coordinate from the linear index by similar logic. I have a truly marvelous demonstration of this, which this page is too small to contain. So I'll skip the math lecture and just give you the final method.

``````function coordinateFromLinearIndex(idx, max_x, max_y){
x =  idx % (max_x+1)
idx /= (max_x+1)
y = idx % (max_y+1)
idx /= (max_y+1)
z = idx
return (x,y,z)
}
``````
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Great answer! I guess I'll just puzzle over your marvelous proof for 375 more years (but it makes sense now). Thanks a bunch. –  user1438116 Jun 5 '12 at 20:42

If you have no upper limit on the coordinates, you can number them from origo and outwards. Layer by layer.

``````(0,0,0) -> 0
(0,0,1) -> 1
(0,1,0) -> 2
(1,0,0) -> 3
(0,0,2) -> 4
:       :
(a,b,c) -> (a+b+c)·(a+b+c+1)·(a+b+c+2)/6 + (a+b)·(a+b+1)/2 + a
``````

The inverse is harder, since you would have to solve a 3rd degree polynomial.

``````m1 = InverseTetrahedralNumber(n)
m2 = InverseTriangularNumber(n - Tetra(m1))
a = n - Tetra(m1) - Tri(m2)
b = m2 - a
c = m1 - m2
``````

where

``````InverseTetrahedralNumber(n) = { x ∈ ℕ | Tetra(n) ≤ x < Tetra(n+1) }
Tetra(n) = n·(n+1)·(n+2)/6
InverseTriangularNumber(n) = { x ∈ ℕ | Tri(n) ≤ x < Tri(n+1) }
Tri(n) = n·(n+1)/2
``````

`InverseTetrahedralNumber(n)` could either be calculated from the large analytic solution, or searched for with some numeric method.

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