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Typically, I'm interested in knowing if the the standard template library incurs performance/speed overheads in codes for numerical/scientific computing.

For eg. Is declaring an array as

double 2dmatrix [10][10]

going to give me more performance than

std::vector<std::vector<double> > 2dmatrix(10,std::vector<double>(10,0.0))


I would also appreciate some general ideas, as to whether C has better performance than C++ for scientific computing. I have written my codes in a very Object oriented style using STL , and using C++11 a lot. I am beginning to consider if I should start looking into pure C, if its going to run faster.

Any thoughts on this are welcome.

share|improve this question
If you know the bounds ahead of time, and they are not going to change, then yes, an array is going to be much more performant than std::vector. Vector is a container that is used for dynamic arrays. It uses a resize policy that sacrifices memory in order to save memory allocations by allocating increasingly large chunks as the vector grows. – crush Aug 20 '13 at 18:36
Array is better but if you're not familiar with dynamic allocation, vector is easier to implement a random number of data items. – Chemistpp Aug 20 '13 at 18:37
The vector of vectors is more like a dynamically allocates array of pointers, each pointer pointing to a dynamically allocated array. The data are not contiguous. This may have consequences, which you have to measure. Also, there is a small size overhead which could be important if your vectors are small. The real equivalent would be std::array<std::array<double,10>, 10>. – juanchopanza Aug 20 '13 at 18:38
"better performance" for what? Just allocating items? Not much in it. If you're using C++11, then converting that to C will be...challenging. For many applications, std::vector is a drop-in relacement for C arrays. What precisely do you want to be performant? – SteveLove Aug 20 '13 at 18:40
And as usual with silly ~performance~ questions, the correct answer is to use neither, but to use specialised matrix data type instead ("why" left as an exercise for the reader — hint: it'll be better at processing your data; it'll also use your CPU to the full extent). See Eigen or Armadillo or something like that. – Cat Plus Plus Aug 20 '13 at 18:53
up vote 12 down vote accepted

Given the abstraction it provides, the C++ std::vector is as efficient as it gets: 3 pointers on the stack, and dynamically allocated data that on average does 1 reallocation per element on a linear growth scenario (because the resizing expands the capacity more than proportionally, a factor of 1.5 to 2).

The C equivalent using malloc() and realloc() would be at least as expensive, and more cumbersome (manual resizing etc.). Moreover, the std::vector allows user-defined performance tuning through special allocators (pool-based, stack-allocated, etc.), which in C++11 are not as hard to use as it was in C++98.

If you don't need dynamic resizing, you can code both in C and C++ a static array (or std::array in C++).

In general, for high-performance computing, C++ has more potential for optimization, in particular through the use of function objects that can be inlined (in contrast to regular C function pointers). The canonical example is sorting

int comp( const void* a, const void* b ) {
    return /* your comparison here */;

// C style sorting
qsort( arr, LARGE_SIZE, sizeof( int ), comp ); 
                                       ^^^^ <---- no-inlining through function pointer

// C++11 style sorting (use hand-made function object for C++98
std::sort(std::begin(arr), std::end(arr), [](auto a, auto b) { 
    return comp(&a, &b);
           ^^^^ <----- C++11 lambdas can be fully inlined
share|improve this answer
+1 on C++11 stuff. The inlining is important, and std::array ftw – SteveLove Aug 20 '13 at 18:48
To be fair, std::vector leaves implementation with enough room to hang themselves with less than optimal solutions. As an example, insert(end(), b,e) isn't guaranteed to do the minimal number of resize/reserves if b and e are random access iterators (it is only guaranteed amortized). – Yakk Aug 20 '13 at 21:57
@Yakk sure, the old shoot yourself in the foot vs blow your leg off story. But the member range-insert of std::vector is guaranteed to be efficient, not just amortized as the non-member std::insert algorithm – TemplateRex Aug 20 '13 at 21:57

The overhead of std::vector is:

  • 3 pointers on the stack
  • dynamic allocation (lazily, i.e. it doesn't allocate anything until required)

A stack-allocated array might be faster in some cases (for small amounts of data). For this you can use std::array<T, Length>.

If you need a 2-dimensional grid I would allocate the data in a single vector: std::vector<T>(width * height);. Then you can write a number of helper functions to obtain elements by x and y coordinates. (Or you can write a wrapper class.)

share|improve this answer
Why neccessarily on the stack? vector<vector<int>> is the simplest counterexample – sasha.sochka Aug 20 '13 at 18:43
Why do you say "for small amounts of data"? So is the std::array performance at par with "double 2dmatrix [10][10]"? I actually operate on VERY large matrices. – atmaere Aug 20 '13 at 18:43
If you have a large amount of data then you should not allocate it on the stack because that might cause stack overflow. Also the performance advantage of std::array reduces as it gets larger. – StackedCrooked Aug 20 '13 at 18:46
@atmaere: std::array is a very thin wrapper around a raw array, so the performance should be identical in optimized builds. – Mooing Duck Aug 20 '13 at 18:46
@StackedCrooked: That's what I said :D – Mooing Duck Aug 20 '13 at 18:48

If you know the sizes beforehand and the performance is a bottleneck - use std::array from C++11. It's performance is exactly the same as of C-style arrays because internally it looks like

template<typename T, int N>
struct array {
  T _data[N];

This is a preffered way to use stack-allocated arrays in modern C++. Never use C-style arrays if you have a modern compiler.

share|improve this answer
@JustinMeiners: std::array is implemented with a T arr[N] member. – Xeo Aug 20 '13 at 18:46
@Xeo ah, I misread as std::vector – Justin Meiners Aug 20 '13 at 18:46
+1 for the code. – atmaere Aug 20 '13 at 18:52

If you have no reason to resize an array, and know it's size during compilation (as you do in your first example), the better choice for STL templates is the std::array template. It provides you all the same benefits of a C-style array.

double 2dmatrix[10][10];

// would become

std::array<std::array<double, 10>, 10> 2dmatrix;
share|improve this answer

People are going to say "It depends on what you're doing".

And they are right.

There's an example here where a conventionally-designed program using std::vector was performance tuned, through a series of six stages, and its execution time was reduced from 2700 microseconds per unit of work to 3.7, for a speedup factor of 730x.

The first thing done was to notice that a large percentage of time was going into growing arrays and removing elements from them. So a different array class was used, which reduced time by a large amount.

The second thing done was to notice that a large percentage of time was still going into array-related activities. So the arrays were eliminated altogether, and linked lists used instead, producing another large speedup.

Then other things were using a large percentage of the remaining time, such as newing and deleteing objects. Then those objects were recycled in free lists, producing another large speedup. After a couple more stages, a decision was made to stop trying, because it was getting harder to find things to improve, and the speedup was deemed sufficient.

The point is, don't just sort of choose something that's highly recommended and then hope for the best. Rather get it built one way or another and then do performance tuning like this, and be willing to make major changes in your data structure design, based on what you see a high percentage of time being spent on. And iterate it. You might change your storage scheme from A to B, and later from B to C. That's perfectly OK.

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How long ago was this? Because you'd have to have one hell of a specific problem for a linked-list to beat an array, even with suboptimal array usage, and I find it VERY hard to believe that you could beat the malloc implementation's free list cache with... your own free list cache. – Puppy Aug 20 '13 at 19:35
@DeadMG: 1) How long ago is irrelevant. 2) Every problem is specific. 3) It is understandably hard to believe. Fortunately, that's irrelevant, because the source code, in all iterations, is here. If you give the tuning method a try, on a moderately big program, you could find yourself getting surprisingly large speedups, assuming speed is the goal, because (IME) most good size programs have multiple bottlenecks, in varying sizes, that together add up to nearly all the execution time. – Mike Dunlavey Aug 21 '13 at 0:39
@DeadMG: Regarding the free-list cache: if each object contains a pointer used for linking them into a free-list, it certainly takes less than 10 instructions to push or pop an object on the list. That's going to be an order of magnitude less than using malloc or free, no matter what they do. – Mike Dunlavey Aug 21 '13 at 14:25

In scientific computing, bugs and sub-optimal code are specially frustrating because large amounts of data are incorrectly processed and precious time is wasted.

std::vector might be your bottleneck or your best performer depending on your knowledge of its inner workings. Pay special attention to reserve(), insert(), erase(); consider learning about alignment and processor caching if your program is threaded.

Think about the time you have to spend ensuring consistency -and later hunting for bugs- if you try to do all the memory management by yourself, particularly when you are progressively adding features to your software. At the end of the day, the overhead of std::vector will be the least of your problems.

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For scientific computing you'd be much better off using a dedicated C++ matrix library, such as Armadillo. This not only gives you fast array processing, but also many linear algebra operations that have been thoroughly debugged.

Apart from performance reasons, using a dedicated C++ matrix library will also allow you to considerably reduce the verbosity of your code, make less mistakes, and hence speed up development. One example is that with a C++ matrix library you don't need to worry about memory management.

Lastly, if you really need to go low-level (ie. use memory directly via pointers), C++ allows you to "drop" down to the C level. In Armadillo this is done via the .memptr() member function.

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