# bucket sort analysis

A simple example is bucket sort. For bucket sort to work, extra information must be available. The input a1, a2, . . . , an must consist of only positive integers smaller than m. (Obviously extensions to this are possible.) If this is the case, then the algorithm is simple: Keep an array called count, of size m, which is initialized to all 0s. Thus, count has m cells, or buckets, which are initially empty. When ai is read, increment count[ai] by 1. After all the input is read, scan the count array, printing out a representation of the sorted list. This algorithm takes O(m + n); If m is O(n), then the total is O(n).

Although this algorithm seems to violate the lower bound, it turns out that it does not because it uses a more powerful operation than simple comparisons. By incrementing the appropriate bucket, the algorithm essentially performs an m-way comparison in unit time. This is similar to the strategy used in extendible hashing. This is clearly not in the model for which the lower bound was proven.

My question on above paragraph

1. What does author mean by "it uses a more powerful operation than simple comparisons"?
2. By incrementing the appropriate bucket, how algorithm performs an m-way comparision? By the way what is m-way comparision?
3. How above bucket sort strategy is related to extensible hashing? can any one pls give an example with extensible hashing?

Thanks!

-

1. the `count[arr[i]]` is more 'powerful' then comparison because it is actually `*(count + arr[i])`. each comparison op has 2 possible values: true/false, while this op has much wider range of values, [all possible addresses!] and thus it is more 'powerful'
3. this is basically a hashing, you hash your elements to the range `[0,m]`. the importance and difference here is: two elements are hashed to the same number, if and only if they are identical. this of course can be achieved only if you hash elements with the same [or less] range then the image.