If I need to sort 150,000 entries what would be the fastest way for a beginner in C++ to sort that data? All I have learned so far is bubble sort and I know that isn't that efficient.
thanks nmr
closed as not constructive by casperOne♦ Apr 5 '12 at 14:42As it currently stands, this question is not a good fit for our Q&A format. We expect answers to be supported by facts, references, or expertise, but this question will likely solicit debate, arguments, polling, or extended discussion. If you feel that this question can be improved and possibly reopened, visit the help center for guidance.If this question can be reworded to fit the rules in the help center, please edit the question. 


There is no such thing as a "fastest" sorting algorithm. Like most things in computer science, when you pick an algorithm you accept certain tradeoffs. That being said, for general purposes, quicksort is likely to be the fastest sorting algorithm for inmemory sorts in most typical cases, although in certain cases it is slower than other sorts, especially if your dataset is mostly sorted already. Again, there are always tradeoffs depending on your requirements and data set. For example, mergesort is usually a bit slower than quicksort, but unlike quicksort it is stable (i.e. samevalue keys retain their original order.) Insertion sort has worse averagecase timecomplexity than quicksort, but it is likely to be faster than quicksort for very small data sets. Bubblesort also has worse averagecase time complexity than quicksort, but it can be much faster than quicksort for data sets which are already sorted. Radix sort may also be faster than quicksort if you are sorting integers. And for extremely large data sets where the data is so large that it doesn't fit in memory, external merge sort would be faster than quicksort. Again, it's all about tradeoffs and your data set. But the best answer for general purposes is probably quicksort. For that reason, most implementations of the C++ standard library 


Like DigitalRoss said Radix Sort is the fastest for the CPU architecture. It is able to cheat by using the architecture of the RAM and CPU setup. It is not often taught in computer science because it has this cheating effect and is not really doing the sorts by itself. In most cases Radix is your fastest solution. The only time it would not be fastest is when the list is really small (like less than 10) or when the list is almost sorted already. It really only sorts integers but most things can be converted to a integer in a clock cycle or two such as a float. Converting a float to a "sortable like int" can be done by simply flipping the sign bit and then it can be sorted and then flipping all the sign bits back after sorting. How it basically works is it looks at a number, say 88, and puts it into memory bank 88. Then it looks at the next number, say 23, and then it put it in memory bank 23. If one of the items overlaps then it puts it in the next empty bank. And then when you’re done with the list the list is actually sorted in memory. I just explained the very basic nature of a radix sort just so you get the general idea. There are some other technical details that I left out to keep it simple  I'm sure someone is going to tell me about it. :) 





As a beginner, I'd try them all! Truly. This will give you both practice with C/C++ but also give you a feel for the fact that each sort algorithm has its benefits and drawbacks......including the Bozo sort! , although that one's advantages is mostly to be fun and of occasional use in the context of unrelated stochastic algorithms. Without going to the extreme and reading TAOCP Vol #3 (Donald Knuth), maybe start with this Comparative list of sort algorithms. The list includes Bubble sort Cocktail sort Comb sort Gnome sort Selection sort Insertion sort Shell sort Binary tree sort Library sort Merge sort Inplace merge sort Heapsort Smoothsort Quicksort Introsort Patience sorting Strand sort Tournament sort 


Radix Sort
Radix sort is usually used with integer keys and is an optimal sort. It is probably the fastest of them all for appropriate inputs, and although not frequently referenced today, it is possibly the oldest automated sorting algorithm known. (A more widely applicable sort with similar time complexity would be the aptlynamed quicksort.) Radix sort has the builtin advantage of automatically limiting its comparisons based on the maximum possible number of values for its key. 


It has limitations, but I believe radix sort has the best worst case time. Most other sorts are comparison sorts, and as such cannot do better than O(n log n). 


If it's 150,000 integers, and they are in the range of say, 0 to 10, then tallying them in an array could be pretty quick. 


I am not terribly familiar with sorting algorithms, but since no one else has posted this site, I figured I would. http://www.sortingalgorithms.com/ It has an incredible amount of detail, yet is still accessible to someone that may not be too familiar with all of the concepts. Not to mention that the animations are great for seeing the algorithm in action  something that you normally do not get to see. I hope this helps! 


If you 1) can't make the assumption that the data is partially sorted, 2) can't use People like to criticize the quicksort for poor performance with certain inputs, especially when the user has control of the input. The following approach yields performance matching midpoint selection but expected complexity exponentially approaches O(n log n) as the list grows in size.
For additional performance, you should always switch your quicksort to shell sort for "small" list segments  I've seen lengths from 15100 chosen as the cutoff. 


I tempt to say quicksort, but what does the array contains? Edit If all you want is the median value, it will be faster iterating through the entire array: O(n) Any sorting will be longer than that, quicksort for example os O(nlogn) 


Actually, a modified (bidirectional) bubble can be extremely efficient, such as in the case where the data set is already sorted before adding one element at the end. I've actually used it in one application where a builtin sort wasn't available and that sort was the quickest to implement. Bubble sort will, in that case, execute as if it were an O(n) algorithm, based on n being the number of items added. That's because the efficiency of an algorithm depends entirely on the properties of the data being sorted. The extreme case can be seen if the data is already sorted  bubble sort makes one pass of the data with zero swaps. So asking which is the fastest is not really valid. You should ask which will have the best behavior for random unsorted data sets. Keep in mind that sort performance doesn't really matter that much if you're only sorting 100 items. The difference between 0.1 seconds and 1 second is not that relevant (unless you're sorting multiple times per second in which case you'd be better off finding a better way to manage your data). The performance only really becomes an issues once the data sets get large. I would say that, if you have a builtin sort in whatever environment you're working in, just use that. If you have to implement your own, figure out first the likely disposition of your data sets then choose based on that. 


use std::sort() You can refer Comparison of algorithms, to know different sorting algorithms and their complexity. I would tend to use quicksort. For my production code, I use std::sort ( at least in VC6 STL, std::sort uses quicksort internally) 


In general, quicksort will be the fastest, but it really depends on the data set. For small data sets, quicksort can have more overhead than other algorithms. 


The fastest, both in terms of performance and programming time, would be to use the library's If your goal is to implement the sort yourself, you could go with a Shell sort, which is said to be quick and pretty efficient. If the keys all have similar lengths, maybe a radix sort. More info on both can be found by Googling, probably the most useful references are in Wikipedia. 


The quicksort algorithm is much more efficient than the bubble sort. 

