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I was asked this question in an interview recently. There are N numbers, too many to fit into memory. They are split across k database tables (unsorted), each of which can fit into memory. Find the median of all the numbers. Wasn't quite sure about the answer to this one. |
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Have a look at the "Median of Medians" algorithm in this wikipedia article. Related question: Median-of-medians in Java. Explanation: http://www.ics.uci.edu/~eppstein/161/960130.html |
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For the median of medians you still need to do pivoting. It is an in memory approach. In this case you need to use a streaming approach. In the first pass you find max and min of the sample. Call that U and L for upper an lower bounds. Then set a candidate median at the average of U and L. With a second pass you count the probability of X < candidate. If it's .5 you are done if not, if it's lower you replace L with the candidate, and the candidate with average of candidate and upper. In the other case, same but swap the roles of upper and lower. Essentially it's binary search among possible medians. If you can afford additional disk space, you can at each step filter all the elements between U and L and work only on those going forward, since the median is guaranteed to be included. This brings the complexity down to linear time, just as that of pivoting. |
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Here is what I would do:
Requires O(N) + O(L2_size) steps. |
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Another way to look at this is to go back to the definition of "median." Authors vary in their language, but basically the median is the value which splits a probability distribution into two equal parts. So instead of spending a lot of effort sorting enormous data sets, estimate the distribution and find the middle. As noted above for some distributions the median equals the mean, which is quick and easy to compute. Also, if an exact answer isn't necessary you can use the empirical relationship: mean - mode = 3 * (mean - median). |
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