We have three sets S1, S2, S3. I need to find x,y,z such that x E S1 y E S2 z E S3
let min denote the minimum value out of x,y,z let max denote the maximum value out of x,y,z The range denoted by maxmin should be the MINIMUM possible value
We have three sets S1, S2, S3. I need to find x,y,z such that x E S1 y E S2 z E S3 let min denote the minimum value out of x,y,z let max denote the maximum value out of x,y,z The range denoted by maxmin should be the MINIMUM possible value 

Of course, the fullbruteforce solution described by IVlad is simple and therefore, easier and faster to write, but it's complexity is According to your Algorithm description Consider thinking about some abstract So, here is the approach. We allocate some additional set (let's call it After that, let's sort our new set Determining the minimal distance Now the interesting part comes. What we want to do is to compute some artificial value, let's call it minimal distance and mark it as Consider the following example  this is our
Let's say we want to compute that our minimal distance for element with index 4. In fact, that minimal distance means the best In our case ( Now, we have to fill the gaps. We know that elements we're seeking for, should be from We make a bidirectional run (run left, the run right from current element) seeking for the first elementnotfrom This finding method is what we need: if we select the first element of from In case of my example (counting the distance for element with index number Now, we have to test 4 cases that can happen  and take the case so that our distance is minimal. In our particular case we have the following (elements returned by the previous routine):
We should test every (X, Y, Z) tuple that can be built using these elements, take the tuple with minimal distance and save that distance for our element. In this example, we would say that Yielding the result Now, when we know how to find the distance, let's do it for every element in our After we have that distance value for every element in our set, just select the element with minimal distance and run our distance counting algorithm (which is described above) for it once again, but now save the Pseudocode Here is comes the pseudocode, I tried to make it easy to read, but it's implementation would be more complex, because you'll need to code set lookups *("determine set for element"). Also note that determine tuple and determine distance routines are basically the same, but the second yields the actual tuple.
P.S I'm pretty sure that this method could be easily used for (, , , ... ) tuple seeking, still resulting in good algorithmic complexity. 





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tag ? – Paul R May 18 '10 at 10:14