I have an array of 64 structs that hold a decent amount of data (struct is around 128 bytes, so that's 8192 bytes that need to be re-arragned). The array needs to be sorted based off a single unsigned byte in each struct. An interesting property of my data is that it is likely that there will be many duplicates of sorted value - meaning that if you got rid of all duplicates, the array may only be 10 unique elements long, but this is not a given.

Once sorted, I need to create a stack that stores the size and type that each unique byte-run starts: so if I ended up with sorted values: 4,4,4,9,9,9,9,9,14,14 the stack would be: (4,3), (9,5), (14,2)

I figured that there would be some nice optimizations I could perform under these conditions. If I do heapsort, I can create the stack while I'm sorting, but would this be faster than a qsort and then build the stack afterwords? Would any sorting algorithm run slower because of the large structs I'm using? Any optimizations I can make because I'm only comparing bytes?

BTW: language is c++


  • What would you use for a stack, something homemade or built-in? – Skurmedel Jan 23 '11 at 17:30
  • I want the fastest, so I imagine it will a simple homemade one that uses a fixed buffer. – Pubby Jan 23 '11 at 17:32
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    Do you need to actually sort or do you just need the "stack" that stores the size and type? – ThomasMcLeod Jan 23 '11 at 18:32
  • I need them sorted, but an unstable sort would work too. – Pubby Jan 23 '11 at 19:03

I would imagine that STL will do what you want nicely. Re-writing your own sort routines and containers is likely to be error-prone, and slow. So only worry about if you find it's a bottleneck.

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  • I'm against the use of std for this purpose, as I can't be sure of the way it sorts! I want to use the most efficient implementation, not a generic one. Thanks, though. – Pubby Jan 23 '11 at 17:47
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    @Pepe: You haven't even measured them, but you're against it based on a hunch? STL routines are generally very, very good. Like I said, if you haven't even measured it, then you shouldn't be worrying about it. – Oliver Charlesworth Jan 23 '11 at 17:47
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    @Pepe: If you want to waste your time, and end up with brittle, hard-to-read, hand-written containers and sort routines, etc., then be my guest! But this is not a good approach to developing performance-critical code. – Oliver Charlesworth Jan 23 '11 at 17:58
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    @Pepe If you don't already know how to do this then you won't beat std. – David Heffernan Jan 23 '11 at 19:00
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    @Pepe if you really knew then why are you asking? – David Heffernan Jan 23 '11 at 19:46

In general with large objects it can be faster to sort an array of pointers/indices of the objects rather than the objects. Or sort an array of nodes, where each node contains a pointer/index of the object and the object's sort key (in this case the key is one byte). To do this in C++ you can just supply a suitable comparator to std::sort or std::stable_sort. Then if you need the original objects in order, as opposed to just needing to know the correct order, finally copy the objects into a new array.

Copying 128 bytes is almost certainly much slower than performing a byte comparison, even with an extra indirection. So for optimal performance it's the moves you need to look at, not the comparisons, and dealing in pointers is one way to avoid most of the moving.

You could build your run-length encoding as you perform the copy at the end.

Of course it might be possible to go even faster with some custom sorting algorithm which makes special use of the numbers in your case (64, "around 128", and 1). But even simple questions like "which is fastest - introsort, heap sort or merge sort" are generally impossible to answer without writing and running the code.

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  • Yeah, I was planning on using a byte to store the indices. I am correct when I say that I need a double buffer? – Pubby Jan 23 '11 at 18:52
  • You don't strictly need one: you need to re-arrange an array according to an arbitrary permutation, which can be done in-place by identifying the cycles of the permutation and re-arranging each cycle in turn, using only a single object's worth of additional space. Also: no guarantees, but my guess is that it would be faster to use a word to store the index and another for the sort key, rather than a byte each. So try both and see which you prefer. – Steve Jessop Jan 23 '11 at 19:21
  • Ok, I will experiment. Thanks – Pubby Jan 23 '11 at 19:26

The sort would not be slower because you will be sorting pointer or references to the structs and not the actual struct in memory.

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The fact that your keys are integers, and there really aren't a lot of them, odds are the Bucket Sort, with a bucket size of 1, would be very applicable.

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  • The only problem with this is that I believe I would have to allocate 16384 bytes for buckets, and also need to use a double buffer for the actual data. Is this correct? Would this be faster than a heapsort? – Pubby Jan 23 '11 at 17:51
  • You could just add the buckets as you go along, by using a map of vectors of pointers to your data. – Null Set Jan 23 '11 at 18:54
  • I have feeling that all the allocation in the vectors would slow that down. – Pubby Jan 23 '11 at 19:02
  • declare the array static, and make it integer. It will run like lightening. – EvilTeach Jan 23 '11 at 21:18

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