Can this code be vectorised further to eliminate loop?

I am working on a ray-tracing geometry problem in MATLAB and have reached a bottleneck in my program.

The function takes in the start and end points of a ray (lStart and lEnd), a set of plane-points and normals (pPoint and norms). The function then computes the distance along the ray at which it intersects each of the planes.

Here is a reference to the original equation: https://en.wikipedia.org/wiki/Line%E2%80%93plane_intersection#Algebraic_form

The code I have so far is as follows:

``````dists = (diag(bsxfun(@minus, pPoint, lStart) * norms')) ./ ((lEnd - lStart) * norms')';
``````

Which was called in a loop such as:

``````nRays   = size(lStart, 1);
nPlanes = size(pPoint, 1);
dists   = zeros(nPlanes, nRays);

for rayCtr = 1:nRays

dists(:, rayCtr) = (diag(bsxfun(@minus, pPoint, lStart(rayCtr, :)) * norms')) ./...
((lEnd(rayCtr, :) - lStart(rayCtr, :)) * norms')';

end
``````

This works perfectly well for a single ray.

Given one ray [1 x 3] and 300 planes [300 x 3], I get a [300 x 1] matrix with the distance of each plane intersection.

What I am struggling with is, vectorising this to work on a list of rays.

Sizes in a typical dataset are:

``````lStart, lEnd  = [14e6, 3];
pPoint, norms = [300,  3];
``````

The ray processing is usually batched into tens of thousands - to fit in memory. For each batch, I'd like to eliminate the `rayCtr` loop. With this method the entire program takes just over 8 hours (32-bit, Windows, 2GB RAM).

Here are some coordinates for six planes (forming a cuboid) and two rays as a MWE:

``````pPoint = [-0.5000   -0.5000   -0.5000;
-0.5000   -0.5000    0.5000;
-0.5000   -0.5000   -0.5000;
-0.5000    0.5000   -0.5000;
-0.5000   -0.5000   -0.5000;
0.5000   -0.5000   -0.5000]

norms = [0  0   1;
0  0   1;
0  1   0;
0  1   0;
1  0   0;
1  0   0]

lStart = [-1 0 0;
-1 0.25 0]

lEnd   = [1 0 0;
1 0.25 0]
``````

The expected output from the example is:

``````dists = [-Inf -Inf;
Inf  Inf;
-Inf -Inf;
Inf  Inf;
0.25 0.25;
0.75 0.75]
``````

Many thanks.

UPDATE: With the solutions proposed in the accepted answer, runtime is down to approximately 30 mins - now limited by read-write operations and voxel lookup.

• Can you give a small numerical example? Which are the 1x3 and 300x3 variables? – Luis Mendo Nov 9 '15 at 13:12
• @LuisMendo does that make sense? – Adam Sroka Nov 9 '15 at 13:35
• Sorry, I seem to have input the wrong rays! Editted to fix. – Adam Sroka Nov 9 '15 at 13:50
• Can you add a for-loop code to solve it, so that people could verify back any optimization possible? – Divakar Nov 10 '15 at 20:28
• @Divakar Sorry, should I add in the for loop I was using originally to show how the code previously worked? – Adam Sroka Nov 11 '15 at 9:33

I think what you need is

``````dists=sum(bsxfun(@times,bsxfun(@minus,...
permute(pPoint,[1 3 2]),permute(lStart,[3 1 2])),...
permute(norms,[1 3 2])),3)...
./(sum(bsxfun(@times,...
permute(lEnd-lStart,[3 1 2]),permute(norms,[1 3 2])),3))
``````

This assumes that `pPoint` and `norms` are size `[nlay 3]`, while `lStart` and `lEnd` are size `[nray 3]`. The result is of size `[nlay nray]`, each corresponding to a (layer,ray) pair.

This gives the correct result for your example:

``````dists =

-Inf      -Inf
Inf       Inf
-Inf      -Inf
Inf       Inf
0.2500    0.2500
0.7500    0.7500
``````

Here's another way to introduce some `fast matrix-multiplication` into play for the denominator part calculations -

``````p1 = sum(bsxfun(@times,bsxfun(@minus,pPoint,permute(lStart,[3 2 1])),norms),2)
p2 = norms*(lEnd - lStart).'
dists = squeeze(p1)./p2
``````

Since `lStart` is listed as a heavy dataset, it might be better to keep it as it is and permute things around it. Thus, one alternative approach to get `squeeze(p1)` would be with -

``````squeeze(sum(bsxfun(@times,bsxfun(@minus,permute(pPoint,[3 2 1]),lStart),permute(norms,[3 2 1])),2)).'
``````
• wow, quick work! This worked fine for me, once my run with real data completes in a few hours, I'll trial again with this. If it works I'll dance a small jig, then accept your answer and be eternally grateful. – Adam Sroka Nov 9 '15 at 13:45
• @AdamSroka unfortunately quick is useless if it's wrong. Luis Mendo will probably come up with a proper solution while I try to debug mine:) – Andras Deak Nov 9 '15 at 13:46
• Sorry, I think I gave you the wrong inputs in the MWE – Adam Sroka Nov 9 '15 at 13:52
• @AdamSroka no problem at all, I'm glad that it was working all along:) Which is especially good, as I couldn't find my error for the life of me:D – Andras Deak Nov 9 '15 at 14:03
• @AdamSroka, also, if time is crucial, you should try the original implementation as well, where the ray index was first in the operations (just switch `1 3` to `3 1` and vice versa in every `bsxfun` call). Due to matlab's column-major memory access, it's possible that there's a reasonable performance difference (since one of the indices is a few hundreds, the other millions). Then of course the output matrix is also transposed, which can be reversed by a single transpose if necessary. – Andras Deak Nov 9 '15 at 14:06