# How to calculate median of a Map<Int,Int>?

For a map where the key represents a number of a sequence and the value the count how often this number appeared in the squence, how would an implementation of an algorithm in java look like to calculate the median?

For example:

``````1,1,2,2,2,2,3,3,3,4,5,6,6,6,7,7
``````

in a map:

``````Map<Int,Int> map = ...
map.put(1,2)
map.put(2,4)
map.put(3,3)
map.put(4,1)
map.put(5,1)
map.put(6,3)
map.put(7,2)

double median = calculateMedian(map);
print(median);
``````

would result in:

``````> print(median);
3
>
``````

So what i am looking for is a java implementation of `calculateMedian`.

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If this is homework, please tag as such. – danben Jun 16 '10 at 11:48
Is this homework? If so please tag it as such. – rsp Jun 16 '10 at 11:50
@danben: for me it isn't homework, but i'm sure for someone it is – Chris Jun 16 '10 at 11:50
In other words, you're a teacher? :) – BalusC Jun 16 '10 at 13:28
@BalusC: no i am not, i am just interested in possible solutions. almost for every question i asked in the past i had a solution already at hand during writing a question here. it's often very intersting how other people would solve it. Btw, it's a google interview question although they ask it in a different way ;) – Chris Jun 16 '10 at 13:36

Using Guava:

``````Multiset<Integer> values = TreeMultiset.create();
``````

``````return Iterables.get(values, (values.size() - 1) / 2);
``````

Really. That's it. (Or check if size is even and average the two central values, to be precise about it.)

If the counts are particularly large, it would be faster to use the multiset's `entrySet` and keep a running sum, but the simplest way is usually fine.

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Of course, in this particular toy example you're probably better off creating and then sorting an `ArrayList` instead of using a `TreeMultiset`, but in real life this might not be memory-friendly. – Kevin Bourrillion Jun 16 '10 at 15:24
That's pretty slick! – BalusC Jun 17 '10 at 22:02
and how would an example for a map look like? sorry, but i know how to calculate the median of a simple sequence for that i dont need a framework. – Chris Jun 19 '10 at 16:17
Why would you want to use a map? The `TreeMultiset` implementation internally uses a map, but presents an API to you that's more appropriate for the kind of thing you're doing. It is not a "simple sequence", it just can appear like one if you want it to. – Kevin Bourrillion Jun 21 '10 at 19:46

Linear time

If you know the total of the numbers (in your case it is 16) you can go from the beginning or the end of the map and sum up the counts until you get to round(n/2)th element, or in case the sum is even to average of floor(n/2)th and ceil(n/2)th elements = median.

If you don't know the total count you will have to go through all of them at least once.

Sublinear time

If you can decide on the data structure and can do pre-processing see wikipedia on selection algorithm and you might get even sublinear algorithm. You can also get sublinear time if you know something about the distribution of the data.

EDIT: So under assumption that we have a sequence with counts what we can do is

• while inserting the `key -> count` pairs maintain another map - `key -> running_total`
• this way you will have a structure in which you will be able to get total_count by looking at the last key's running_total
• and you will be able to do a binary search to locate the element where running total is close to total_count/2

This will double the memory usage, but will give O(log n) performance for median and O(1) for total_count.

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+1 I actually use this approach some times to calculate the median as no additional sorting is required. If you work on bounded, discrete values (with a low upper bound), you can even bucket-sort (like, create a histogram). – zerm Jun 16 '10 at 13:00
@Rafał, actually this assumes that access to a key is O(1) and not much else, (OP specified key values to be equal to certain range and I assume no holes => sorted); also it is the `running_total` that is important here, I simply kept the data structure the same as in OP. – Unreason Jun 16 '10 at 14:18
• Use a `SortedMap`, i.e. a `TreeMap`
• Iterate through the map once to calculate the total number of elements, i.e. the sum of all occurrences
• Iterate again and add up occurences until you've reached half of the total. The number that caused the sum to exceed half of the total is the median
• Test extensively for off-by-one errors
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half the total? Half the total is going to drop you near the element that is almost, but not quite the mean, if you are lucky. If you have 'n' elements in your SortedMap, the median is going to be the element at 'n/2'. – McBeth Jun 16 '10 at 12:04
Nice approach, but needs a bit more refining... if you have a list 1,2,2,4,4,5 you algorithm would return 2 or 4 depending on insertion order, when the correct median value would be 3. – kasperjj Jun 16 '10 at 12:04
@McBeth: the mean is not what is wanted. And the median is not necessarily the element at n/2 due to the occurrences count – Michael Borgwardt Jun 16 '10 at 12:26
@kasperjj: Yes, that's a rare special case that would need extra code if you really need to support it. – Michael Borgwardt Jun 16 '10 at 12:29
+1 as it seems that basically I've written the same thing (I did mention testing for odd/even); also since OP talks about sequences and counts would you really need SortedMap? – Unreason Jun 16 '10 at 12:31

For in easy but maybe not-so-efficient algorithm I'd do it like this:

1. expand the map to a list.

practically spoken: iterate through the map and add the key 'value-times' to the new list. Finally sort the list.

``````//...
List<Integer> field = new ArrayList<Integer>();
for (Integer key:map) {
for (int i = 0; i < map.get(key); i++) {
}
}
Collections.sort(field);
``````

2. calculate the median

now you have to implement a method `int calculateMedian(List<Integer> sorted)`. This depends on the kind of median you need. If it's just the sample median, then the result is either the middlemost value (for lists with an odd number of elements) or the average of the two middlemost values (for lists with an even length). Note, that the list needs to be sorted!

OK, OK, even though Chris didn't mention efficiency, here's an idea how to calculate the sample median (!) without expanding the map...

``````Set<Integer> sortedKeys = new TreeSet<Integer>(map.keySet()); // just to be sure ;)
Integer median = null;  // Using Integer to have a 'invalid/not found/etc' state
int total = 0;
for (Integer key:sortedKeys) {
total += map.get(key);
}
if (isOddNumber(total)) { // I don't have to implement everything, do I?
int counter = total / 2;  // index starting with 0
for (Integer key:sortedKeys) {
middleMost -= map.get(key);
if (counter < 0) {
// the sample median was in the previous bin
break;
}
median = key;
}
} else {
int lower = total/2;
int upper = lower + 1;
for (Integer key:sortedKeys) {
lower -= map.get(key);
upper -= map.get(key);
if (lower < 0 && upper < 0) {
// both middlemost values are in the same bin
break;
} else (lower < 0 || upper < 0) {
// lower is in the previous, upper in the actual bin
median = (median + key) / 2; // now we need the average
break;
}
median = key;
}
}
``````

(I have no compiler at hand - if it has to many syntax errors, treat it as pseudo code, please ;) )

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@Andreas: +1 That is how I should do it... – Martijn Courteaux Jun 16 '10 at 12:21
-1: the point is, I think, that Chris does not want to expand the list, since it could be very inefficient indeed. – Michael Borgwardt Jun 16 '10 at 12:25
I agree with Michael, though the answer is very clear it simply unnecessary expands the list killing a lot of memory while the algorithms that provide solution without expanding the list are quite simple (therefore I simply can't see justification for this). – Unreason Jun 16 '10 at 12:36
Simple? maybe in terms of lines of code but an algorithm that is based on expanding on a list is much easier to read and understand. AND - now we have a very specialized agorithm for a special map. Reusability of the median calculation part is close to zero. – Andreas_D Jun 16 '10 at 13:47
Re complexity, I do agree your approach is simpler, however the second implementation is not complicated: two loops and some counting. The simplicity of the first approach has memory requirements are x times higher (x is the average of all the counts; from the sample data in question this is ~2.3, in real case this can be any integer, let us assume 100). Also, if expanding the complexity of the sort grows by log x, loop times grow by x. So the algorithm uses more memory and it is slower. – Unreason Jun 16 '10 at 15:18