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What is considered an optimal data structure for pushing something in order (so inserts at any position, able to find correct position), in-order iteration, and popping N elements off the top (so the N smallest elements, N determined by comparisons with threshold value)? The push and pop need to be particularly fast (run every iteration of a loop), while the in-order full iteration of the data happens at a variable rate but likely an order of magnitude less often. The data can't be purged by the full iteration, it needs to be unchanged. Everything that is pushed will eventually be popped, but since a pop can remove multiple elements there can be more pushes than pops. The scale of data in the structure at any one time could go up to hundreds or low thousands of elements.

I'm currently using a std::deque and binary search to insert elements in ascending order. Profiling shows it taking up the majority of the time, so something has got to change. std::priority_queue doesn't allow iteration, and hacks I've seen to do it won't iterate in order. Even on a limited test (no full iteration!), the std::set class performed worse than my std::deque approach.

None of the classes I'm messing with seem to be built with this use case in mind. I'm not averse to making my own class, if there's a data structure not to be found in STL or boost for some reason.

edit:

There's two major functions right now, push and prune. push uses 65% of the time, prune uses 32%. Most of the time used in push is due to insertion into the deque (64% out of 65%). Only 1% comes from the binary search to find the position.

template<typename T, size_t Axes>
void Splitter<T, Axes>::SortedData::push(const Data& data) //65% of processing
{
 size_t index = find(data.values[(axis * 2) + 1]);

 this->data.insert(this->data.begin() + index, data); //64% of all processing happens here
}

template<typename T, size_t Axes>
void Splitter<T, Axes>::SortedData::prune(T value) //32% of processing
{
 auto top = data.begin(), end = data.end(), it = top;

 for (; it != end; ++it)
 {
  Data& data = *it;

  if (data.values[(axis * 2) + 1] > value) break;
 }

 data.erase(top, it);
}

template<typename T, size_t Axes>
size_t Splitter<T, Axes>::SortedData::find(T value)
{
 size_t start = 0;
 size_t end = this->data.size();

 if (!end) return 0;

 size_t diff;

 while (diff = (end - start) >> 1)
 {
  size_t mid = diff + start;

  if (this->data[mid].values[(axis * 2) + 1] <= value)
  {
   start = mid;
  }
  else
  {
   end = mid;
  }
 }

 return this->data[start].values[(axis * 2) + 1] <= value ? end : start;
}
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1  
Profiling shows it taking up the majority of the time. Which operation is taking more time? Could you post the code, so we can see what you're actually doing? –  Nawaz Jan 28 '13 at 16:14
    
Wouldn't a map fullfill all requirements barring pushing/popping N elements at once? And you could just do N 'pushes' or 'pops' (insert(), erase()) to get that. Remember to use pre-inc on your iterators! :-) –  Grimm The Opiner Jan 28 '13 at 16:20
    
Don't you mean set? Using the set with a barebones setup, so insert for the push, and begin plus lower_bound to get iterators plugged into an erase for pop, I got worse performance than with a deque. –  user173342 Jan 28 '13 at 16:22
    
If it's not key/value, I guess I do. If it's a complex data type and you wrote it, you'll have written your own comparitor or operator()? Try to make THAT faster? And make sure it takes arguments by reference! :-) –  Grimm The Opiner Jan 28 '13 at 16:27
    
If you say "The data can't be purged by the full iteration", does that mean you cannot simply grab a copy and sort it, or sort it before you iterate? What if the data structure appears sorted whenever you query for it from the outside, but actually changes internally? –  ltjax Jan 28 '13 at 17:10

5 Answers 5

up vote 2 down vote accepted

With your requirements, a hybrid data-structure tailored to your needs will probably perform best. As others have said, continuous memory is very important, but I would not recommend keeping the array sorted at all times. I propose you use 3 buffers (1 std::array and 2 std::vectors):

  • 1 (constant-size) Buffer for the "insertion heap". Needs to fit into the cache.
  • 2 (variable-sized) Buffers (A+B) to maintain and update sorted arrays.

When you push an element, you add it to the insertion heap via std::push_heap. Since the insertion heap is constant size, it can overflow. When that happens, you std::sort it backwards and std::merge it with the already sorted-sequence buffer (A) into the third (B), resizing them as needed. That will be the new sorted buffer and the old one can be discarded, i.e. you swap A and B for the next bulk operation. When you need the sorted sequence for iteration, you do the same. When you remove elements, you compare the top element in the heap with the last element in the sorted sequence and remove that (which is why you sort it backwards, so that you can pop_back instead of pop_front).

For reference, this idea is loosely based on sequence heaps.

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Interesting. I have some debugging and such to do, then I'll digest your idea and try to get a test working. And thanks a lot, I was getting a little disheartened by "use a map!" suggestions. –  user173342 Jan 28 '13 at 19:16
    
YW, node-based containers are bad except for theoretical performance analysis :) However, note that the theoretical performance of this data structure will become very bad if the size of the insertion buffer becomes a lot smaller than that of the sorted sequence. With just a few thousand elements, you should be able to find constants where this does not happen tho. –  ltjax Jan 28 '13 at 19:26
    
Turns out this idea didn't perform better than that basic deque thing either, probably cause my object size is 16 bytes. However, simply making my own really stripped down "vector" class that did nothing wasteful and sorting things greatest to least using std::upper_bound on insert allowed me to go from ~10000 microseconds per test to ~235. This is no longer near the most time consuming portion of my code, so problem solved I guess. Perhaps using non-STL containers with your algorithm (or at least no vectors!) could push things further. –  user173342 Jan 28 '13 at 23:24
    
Interesting, I wouldn't think that std::vector had any noticeable overhead over a plain array, unless you are compiling in debug. Which size did you use for the insertion buffer? –  ltjax Jan 29 '13 at 15:40
    
I tried many sizes on the insertion buffer, and got the best performance when it was larger than my dataset (lol). So at about 4096 I stopped getting a speed up. At that point it was ~3000 microseconds per test. Anyway, here's why I didn't use vector, erase is "Linear on the number of elements erased (destructions) plus the number of elements after the last element deleted (moving)." All I wanted was O(1) "count" to be decremented. Maybe it gets optimized out by the compiler or something, I dunno. I might try swapping in vector and checking speeds. –  user173342 Jan 29 '13 at 16:12

Have you tried messing around with std::vector? As weird as it may sound it could be actually pretty fast because it uses continuous memory. If I remember correctly Bjarne Stroustrup was talking about this at Going Native 2012 (http://channel9.msdn.com/Events/GoingNative/GoingNative-2012/Keynote-Bjarne-Stroustrup-Cpp11-Style but I'm not 100% sure that it's in this video).

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Might well need the whole vector re-allocating in the event of an insert, and requires the OP to do their own sorting. –  Grimm The Opiner Jan 28 '13 at 16:23
    
I've considered sorting in reverse with a vector. The deque implementation in VC++ 11 appears to be simply data centered in a vector, though. I'll probably get marginal gains from that, but with the hefty price for insertion remaining. –  user173342 Jan 28 '13 at 16:24
    
I'm not saying that's it's perfect solution, but if you know how many elements you could have in container you could allocate memory at the beginning. And by using binary_search to find right place in vector inserting would be pretty fast too. In my opinion most of time wasted in deque or map would be jumping around in memory. Of course using them would be easier, and intention would be clearer, but nonetheless vector could be faster (and it seems that speed is top priority here). Edit: I haven't seen your reply 'user173342' ;] –  Dino Jan 28 '13 at 16:28
    
If you don't want to write a std::vector based solution yourself, there are several sorted vector implementations. boost::flat_multiset and I'm sure Loki provides something similar. –  Dave S Jan 28 '13 at 17:04

You save time with the binary search, but the insertion in random positions of the deque is slow. I would suggest an std::map instead.

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1  
I have nothing to map to. It would be a set. I tested the performance and it is significantly worse. And that's without full iteration, which the deque will obviously be better at. –  user173342 Jan 28 '13 at 16:22
    
You are right, it would be a set, not a map. Both are slower than a deque when inserting/removing at the ends of the sequence, but the deque is much slower when inserting/removing in the middle. –  comocomocomocomo Jan 28 '13 at 18:22
    
Oh, and just in case... did you remove the "find()" function when tested the set? (You should) –  comocomocomocomo Jan 28 '13 at 18:27
    
I changed the code to match the data structure. Find would throw an error with a set, anyway. My code with set was much simpler and used none of "my own" code (only set's insert, begin, lower_bound, and erase). Prune was accomplished with erase(data.begin(), data.lower_bound(value)) –  user173342 Jan 28 '13 at 18:33
    
That's pretty strange, then. A search tree should save a lot of that 65% time that you are wasting on insertions. Maybe the problem of the set is the memory allocation of the nodes, one by one. In this case, a pool allocator might help. –  comocomocomocomo Jan 29 '13 at 4:01

You can't do any better than o(log n) sorted insertion time, which a set and a priority_queue (which builds off of deque anyway) will do. You could look into STL's map, but I don't think you'll see any improvement there.

It sounds to me that what you're saying is that the optimized STL insertion operations just don't happen fast enough for you. If this is the case I would suggest looking into your comparison function and possibly optimizing that, or consider writing your own data structure(s) that perform the same operations, but could possibly take advantage of assumptions about the objects in your container, and then optimize the heck out of it first without thinking about any kind of exception handling.

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It isn't to O(log n) insertion that is killing me, it's the moving data in the deque (or alternatively, a vector). It's still better than using a set, but I was wondering if there's something made for this purpose. –  user173342 Jan 28 '13 at 16:25
    
What do you mean 'moving data'? You said this in your post --> "Most of the time used in push is due to insertion (64% out of 65%)." –  AndyG Jan 28 '13 at 16:27
    
The insertion command to the deque. The other 1% is persumably me finding the position by binary search, which is your O(log n). –  user173342 Jan 28 '13 at 16:28
    
@user173342: Well the issue here is that vectors and deque will perform poorly for insertions NOT at the beginning or end. Its page even says as much (cplusplus.com/reference/deque/deque). A balanced binary tree like a set or a map will be more efficient at insertion, but less so at iteration. It's strange to me that your tests found that deque's insertion was faster. –  AndyG Jan 28 '13 at 16:37
    
@user173342: have you looked into a forward list? (cplusplus.com/reference/forward_list/forward_list) –  AndyG Jan 28 '13 at 16:38

From your edit, it sounds like the delay is in copying - is it a complex object? Can you heap allocate and store pointers in the structure so each entry is created once only; you'll need to provide a custom comparitor that takes pointers, as the objects operator<() wouldn't be called. (The custom comparitor can simply call operator<())

EDIT: Your own figures show it's the insertion that takes the time, not the 'sorting'. While some of that insertion time is creating a copy of your object, some (possibly most) is creation of the internal structure that will hold your object - and I don't think that will change between list/map/set/queue etc. IF you can predict the likely eventual/maximum size of your data set, and can write or find your own sorting algorithm, and the time is being lost in allocating objects, then vector might be the way to go.

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Using pointers to perform all those comparisons would inevitably result in a slowdown (requires cache line for each object in the heap). The object isn't very large, 16 bytes. –  user173342 Jan 28 '13 at 16:35

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