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Today I decided to benchmark and compare some differences in gcc optimizability of std::vector and std::array. Generally, I found what I expected: performing a task on each of a collection of short arrays is much faster than performing the tasks on a collection equivalent vectors.

However, I found something unexpected: using std::vector to store the collection of arrays is faster than using std::array. Just in case it was the result of some artifact of a large amount of data on the stack, I also tried allocating it as an array on the heap and in a C-style array on the heap (but the results still resemble an array of arrays on the stack and a vector of arrays).

Any idea why std::vector would ever outperform std::array (on which the compiler has more compile-time information)?

I compiled using gcc-4.7 -std=c++11 -O3 (gcc-4.6 -std=c++0x -O3 should also result in this conundrum). Runtimes were computed using the bash-native time command (user time).

Code:

#include <array>
#include <vector>
#include <iostream>
#include <assert.h>
#include <algorithm>

template <typename VEC>
double fast_sq_dist(const VEC & lhs, const VEC & rhs) {
  assert(lhs.size() == rhs.size());
  double result = 0.0;
  for (int k=0; k<lhs.size(); ++k) {
    double tmp = lhs[k] - rhs[k];
    result += tmp * tmp;
  }
  return result;
}

int main() {
  const std::size_t K = 20000;
  const std::size_t N = 4;

  // declare the data structure for the collection
  // (uncomment exactly one of these to time it)

  // array of arrays
  // runtime: 1.32s
  std::array<std::array<double, N>, K > mat;

  // array of arrays (allocated on the heap)
  // runtime: 1.33s
  //  std::array<std::array<double, N>, K > & mat = *new std::array<std::array<double, N>, K >;

  // C-style heap array of arrays
  // runtime: 0.93s
  //  std::array<double, N> * mat = new std::array<double, N>[K];

  // vector of arrays
  // runtime: 0.93
  //  std::vector<std::array<double, N> > mat(K);

  // vector of vectors
  // runtime: 2.16s
  //  std::vector<std::vector<double> > mat(K, std::vector<double>(N));

  // fill the collection with some arbitrary values
  for (std::size_t k=0; k<K; ++k) {
    for (std::size_t j=0; j<N; ++j)
      mat[k][j] = k*N+j;
  }

  std::cerr << "constructed" << std::endl;

  // compute the sum of all pairwise distances in the collection
  double tot = 0.0;
   for (std::size_t j=0; j<K; ++j) {
     for (std::size_t k=0; k<K; ++k)
       tot += fast_sq_dist(mat[j], mat[k]);
   }

   std::cout << tot << std::endl;

  return 0;
}

NB 1: All versions print the same result.

NB 2: And just to demonstrate that the runtime differences between std::array<std::array<double, N>, K>, std::vector<std::array<double, N> >, and std::vector<std::vector<double> > wasn't simply from assignment/initialization when allocating, the runtimes of simply allocating the collection (i.e. commenting out the computation and printing of tot) were 0.000s, 0.000s, and 0.004s, respectively.

NB 3: Each method is compiled and run separately (not timed back-to-back within the same executable), to prevent unfair differences in caching.

NB 4:
Assembly for array of arrays: http://ideone.com/SM8dB
Assembly for vector of arrays: http://ideone.com/vhpJv
Assembly for vector of vectors: http://ideone.com/RZTNE

NB 5: Just to be absolutely clear, I am in no way intending to criticize STL. A absolutely love STL and, not only do I use it frequently, details of effective use have taught me a lot of subtle and great features of C++. Instead, this is an intellectual pursuit: I was simply timing things to learn principles of efficient C++ design. Furthermore, it would be unsound to blame STL, because it is difficult to deconvolve the etiology of the runtime differential: With optimizations turned on, it can be from compiler optimizations that slow the code rather than quicken it. With optimizations turned off, it can be from unnecessary copy operations (that would be optimized out and never be executed in production code), which can be biased against certain data types more than others.

If you are curious like me, I'd love your help figuring this out.

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4  
Try running it with an iteration count of like 1000 to see more accurate values. Those look like they just could be latency values. –  Cole Johnson Jul 1 '12 at 1:59
    
@ColeJohnson Do you mean N=1000 or K=1000? If you mean N=1000, a vector of arrays is nearly identical to vector of vectors (because the overhead of not unrolling the loop is very high). Using N=1 results in a much higher difference between vector of arrays and vector of vectors, because vector of array should be essentially converted into vector of double. So the most interesting case for comparing array of arrays and vector of arrays is K << N (<< in the math sense, not the bit shift sense). –  Oliver Jul 1 '12 at 2:04
    
What happens if you swap the two tests? –  Mehrdad Jul 1 '12 at 2:09
1  
@Oliver: Like, do the array test after the vector test. Or wait, are you testing them on separate programs entirely? If so, I misunderstood then. –  Mehrdad Jul 1 '12 at 2:11
    
Their respective internal representations are way too similar to have any discrepancies in performance. This is not really a valid test, you need a bigger data set. –  user1309389 Jul 1 '12 at 2:13

6 Answers 6

Consider the second and third tests. Conceptually, they are identical: Allocate K * N * sizeof(double) bytes off the heap and then access them in exactly the same way. So why the different times?

All of your "faster" tests have one thing in common: new[]. All of the slower tests are allocated with new or on the stack. vector probably uses new[] Under the Hood™. The only obvious cause for this is that new[] and new have more significantly different implementations than expected.

What I'm going to suggest is that new[] will fall back to mmap and allocate directly on a page boundary, giving you an alignment speedup, whereas the other two methods will not allocate on a page boundary.

Consider using an OS allocation function to directly map committed pages, and then place a std::array<std::array<double, N>, K> into it.

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I tried std::array<std::array<double, N>, K > & mat = *new std::array<std::array<double, N>, K >[1]; to force use of new[], but it gives the same runtime as array of arrays... –  Oliver Jul 1 '12 at 3:24
9  
Unless you supply an allocator to do so, vector will not use new[] "under the hood". It uses whatever the allocator supplies. Unless you specify otherwise, it uses std::allocator<T>. That, in turn, will use operator new to allocate raw memory. –  Jerry Coffin Jul 1 '12 at 3:33
    
Oh yeah. Forgot about allocators. –  Puppy Jul 1 '12 at 4:11
    
The alignment speedup wouldn't account for this. Total memory usage is 20000*4*8 ≈ 640K, so not much time is getting spent allocating pages. –  Potatoswatter Jul 1 '12 at 8:34
    
So what is the answer? :s –  mezamorphic Jul 16 '13 at 12:48

I suspect that when allocating the array on the stack or heap the compiler just has to align for array while when using vector's allocator it's probably using operator new which has to return memory suitably aligned for any type. If that allocated memory happened to be better aligned allowing more cache hits/bigger reads, then that seems like it could easily explain the performance difference.

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+1 Nice thought. I've already tried it with int as the internal type (with similar results), but I wonder if using other types would align array better? Maybe worth trying with float, char, T*, etc. Also, your answer would explain why the speed difference still occurs with optimizations at -O0, -O, and -O3. –  Oliver Jul 3 '12 at 18:35

Don't search for complicated explanations when simple ones are enough. It's an optimizer bug. Plain old fixed-size C-style stack-allocated array gives performance similar to std::array, so don't blame std::array implementation.

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I did not say you have blamed STL. I'm only saying you shouldn't, just in case. BTW I have tried it with -O2 and all variants have had virtually identical performance.l on my machine. –  n.m. Jul 1 '12 at 18:57
    
Interesting... perhaps if you tried increasing K? I am running on a core i7, but a laptop nonetheless, so it may need larger scale to be apparent on better hardware. Regardless, I'm shocked that vector of array wasn't faster than vector of vectors for you-- that one makes intuitive sense to me (when K is much larger than N). Isn't that one surprising to you? –  Oliver Jul 1 '12 at 19:00

One thing that pops to mind for me is that such a large object on the stack in one go may trigger a reallocation of the stack space by the OS. Try dumping /proc/self/maps at the end of main

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2  
Huh, is that something an OS can actually do? I would think that reallocating the stack would invalidate any pointers-to-stack-objects the program might have, resulting in a likely crash of the program... –  Jeremy Friesner Jul 1 '12 at 3:41
1  
To make sure it wasn't caused by using the stack in this way, I have one test above where I allocate the array of arrays on the heap-- I get the same runtime. –  Oliver Jul 1 '12 at 3:47
    
@Jeremy: Yes it is. Reallocation isn't a problem because the address of the stack is down the other end of the virtual memory address space from the heap and things allocated with mmap. Physical pages can just be mapped on to the end. –  notlostyet Jul 1 '12 at 10:06
    
The most interesting difference for me is between the stack allocated std::array and the new allocated std::array (cases 1 and 2). –  notlostyet Jul 1 '12 at 12:39
1  
The assembly diff for my machine (i5, gcc 4.7.1, -O3) is here: ideone.com/udMVz . On my machine the stack version takes 1.75 seconds (avg over 100 runs), and the new allocated std::array 1.45 seconds. The only difference I can see is the instruction re-ordering starting on line 15 (label L2), but that's outside the arithmetic loop. I also checked that the stacked array is 16byte aligned. Perhaps as the array is populated several page faults occur and the stack is reallocated by the Linux kernel? –  notlostyet Jul 1 '12 at 12:44

The only big difference I see is that your data is stored differently. In your first two cases your data is stored in one huge chunk. All other cases store pointers to the rows in your matrix. I don't quite know why that makes your code faster but it could be related to lookups and CPU prefetching. Try caching your matrix row before you iterate over it so you don't need to look up mat[k] for every entry. That could make it faster and even the speeds out. It could be that your compiler can do this in the vector<array<T>> case but not in the array<array<T>> case.

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I think that array<array<T> > and vector<array<T> > both store it in one large block (except vector stores the block on the heap). array<vector<T> > or vector<vector<T> > do more of what you're saying (storing a collection of pointers, one for each row). –  Oliver Jul 1 '12 at 18:40
    
@Oliver: You're right. –  Florian Jul 1 '12 at 19:30

I just tried it on my desktop with MSVC++ 2010, and I got the same time (1.6 seconds) for all the tests except vector of vectors which was 5.0 seconds.

I would consider looking at your libraries actual implementation of array and vector to see if there are any obvious differences.

Try replacing index-style loops with iterator-style loops and see if that affects performance.

Also, try using clock() to time your program from within the program: among other things, this would let you tell which part of the code is acting differently. It might even be worth adding in a nested scope so you can time the object destructors as well.

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