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I am reading introduction to algorithms 2nd edition, and there is a question says that we can sort n integers, who are between 0 and n3-1 in linear time. I am thinking of IBM's radix sort approach. I start with the least significant digit, separate numbers with respect to least significant digit, and then sort, then separate with respect to next least significant digit and so on. Each separation takes O(n) time. But i have a doubt, for example, if one of the number consists of n digits, then the algorithm takes O(1*n+2*n+...+n*n)=O(n2) time, right? Can we assure that numbers consist of fewer than n digits, or can anybody give another hint for the question? Thanks

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Each number is between 0 and n^3 - 1. Thus it will have at most 3 digits base n. –  Ivaylo Strandjev Mar 10 '13 at 15:17
    
thanks, so with this information, my solution works right? –  bigO Mar 10 '13 at 15:18
    
yes I believe so. –  Ivaylo Strandjev Mar 10 '13 at 15:19
    
@IvayloStrandjev: That's basically an answer in my book. You should (re-)post it, though you can give some details on how to do the sort in exactly three passes. –  nneonneo Mar 10 '13 at 16:55
    
related: Sorting in linear time? –  J.F. Sebastian Mar 11 '13 at 15:26

2 Answers 2

up vote 3 down vote accepted

Radix Sort complexity is O(dn) with d as the number of digits in a number.

The algorithm runs in linear time only when d is constant! In your case d = 3log(n) and your algorithm will run in O(nlog(n)).

I'm honestly not sure how to solve this problem in linear time. Is there any other piece of information regarding the nature of the numbers I'm wondering if there is any other piece of information missing about the nature of numbers...

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thanks for the answer, i found the answer actually, we treat the numbers as 2-digit numbers in radix n, then we sort these 2-digit numbers. Total time is O(n) –  bigO Mar 10 '13 at 19:19
    
If you break a number in 2-digit 'keys', don't you end up with 'd = 3log(n) / 2'? do you have a link to a detailed analysis of the algorithm? thanks –  Gevorg Mar 10 '13 at 19:28
    
ACtually, i found it from the instructor's manual of the book, and here is exactly what it says: Treat the numbers as 2-digit numbers in radix n. Each digit ranges from 0 to n −1. Sort these 2-digit numbers with radix sort. There are 2 calls to counting sort, each taking Θ(n + n) = Θ(n) time, so that the total time is Θ(n). –  bigO Mar 10 '13 at 20:10
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@bigO: 1. n**3-1 requires 3 digits in base n. 2. You can't expect that manipulating a digit in base n is O(1) (constant time) for arbitrary large n. –  J.F. Sebastian Mar 10 '13 at 21:04
    
I would downvote this (if I could!). You are (in)conveniently mixing two models of computation... If you think input size is n, then you are implicitly assuming word ram model, in which n fits in O(1) words, but then you switch to bit complexity... –  Knoothe Mar 11 '13 at 3:08

Assuming a word RAM model, and that n fits in O(1) words, there is a linear time algorithm.

Write every number in base n, and do a radix sort (with a stable version of counting sort as the underlying digit sort).

If you want to assume unbounded n, then the size of the input it actually n log n, in which case radix sort again works (in O(n log n) time), and technically speaking, it is still a linear time algorithm! (Of course, I suppose this still assumes arithmetic is O(1)...)

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Is linearithmic actually linear? –  Gevorg Mar 16 '13 at 19:37
    
Just to follow up since we've been talking for a while now! :) I'm not sure how you got to O(nlog(n)) but if you accept this as a linear solution then the problem would be trivially solved with a good implementation of QuickSort, MergeSort, or others... –  Gevorg Mar 17 '13 at 19:27
    
@Gevorg: No, comparing integers would be O(log n), and Quicksort etc will be Theta(n (log n)^2). The underlying computational model is important. Most algorithm textbooks use the WORD RAM model (and in practice most people use that without thinking, as it is the closest to a real computer). In which case (i.e in the WORD RAM model), the input size is Theta(n), radix sort is O(n) and quicksort etc are O(n log n). –  Knoothe Mar 21 '13 at 1:30
    
(again: I am talking about the current problem, where the integers are < n^3). –  Knoothe Mar 21 '13 at 1:41

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