16

First question, is it a good thing to start using c++11 if I will develop a code for the 3 following years?

Then if it is, what is the "best" way to implement a matrix if I want to use it with Lapack? I mean, doing std::vector<std::vector< Type > > Matrix is not easily compatible with Lapack.

Up to now, I stored my matrix with Type* Matrix(new Type[N]) (the pointer form with new and delete were important because the size of the array is not given as a number like 5, but as a variable).

But with C++11 it is possible to use std::array. According to this site, this container seems to be the best solution... What do you think?

6
  • 5
    One question at a time please.
    – Kerrek SB
    Commented Sep 18, 2013 at 9:43
  • @KerrekSB : well, I know but the first question is a yes/no question...
    – PinkFloyd
    Commented Sep 18, 2013 at 9:47
  • 2
    gist.github.com/rmartinho/3959961 Commented Sep 18, 2013 at 10:12
  • 1
    @PinkFloyd: The first question would have got closed immediately for being "primarily opinion-based", and the second technical question would have got more attention. Mixing the two leaves you with an offputting, mediocre question that people might just skip over.
    – Kerrek SB
    Commented Sep 18, 2013 at 10:15
  • @R.MartinhoFernandes I actually wrote more or less exactly the same code for my matrix with c++03. but i have trouble to sort it. this is why i considered using c++11 and maybe use c++11 std::array instead of a pointer
    – PinkFloyd
    Commented Sep 18, 2013 at 10:17

2 Answers 2

20

First things first, if you are going to learn C++, learn C++11. The previous C++ standard was released in 2003, meaning it's already ten years old. That's a lot in IT world. C++11 skills will also smoothly translate to upcoming C++1y (most probably C++14) standard.

The main difference between std::vector and std::array is the dynamic (in size and allocation) and static storage. So if you want to have a matrix class that's always, say, 4x4, std::array<float, 4*4> will do just fine.

Both of these classes provide .data() member, which should produce a compatible pointer. Note however, that std::vector<std::vector<float>> will NOT occuppy contiguous 16*sizeof(float) memory (so v[0].data() won't work). If you need a dynamically sized matrix, use single vector and resize it to the width*height size.

Since the access to the elements will be a bit harder (v[width * y +x] or v[height * x + y]), you might want to provide a wrapper class that will allow you to access arbitrary field by row/column pair.

Since you've also mentioned C-style arrays; std::array provides nicer interface to deal with the same type of storage, and thus should be preferred; there's nothing to gain with static arrays over std::array.

6
  • Thx for your complete answer. But your last remark seems to disagree with "The struct combines the performance and accessibility of a C-style array with the benefits of a standard container, such as knowing its own size, supporting assignment, random access iterators, etc." (see the link i gave i my question)
    – PinkFloyd
    Commented Sep 18, 2013 at 10:12
  • How does it disagree, exactly? I think it spells pretty much the same thing. Commented Sep 18, 2013 at 10:21
  • it seems to me that they are implying that other containers (namely std::vector) are not as efficient a the C-style array, but std::array is... but i don't know enough to compare the efficiency of C-style array, std::vector and std::array.
    – PinkFloyd
    Commented Sep 18, 2013 at 10:33
  • 4
    std::vector has (a very slight) performance impact due to its dynamic nature; because the size of the required memory is not known at compile time, the OS memory allocation call has to be made. C-style arrays and std::array are OTOH of a fixed size and thus they can be allocated on stack without the need to ask OS for more memory. The access to elements is equally fast in both approaches and boils down to simple pointer arithmetic. If you are that serious about performance, you should probably be using SIMD instructions and types to make use of HW-accelerated calculations. Commented Sep 18, 2013 at 10:37
  • 1
    If a std::array is allocated statically (i.e. in the data section; by declaring it outside of any function or with the static keyword inside a function) then won't its address be known at compile time, allowing some optimisations (i.e. no need to dereference a pointer)? So it should be faster? Commented Dec 26, 2013 at 4:09
16

This is a very late reply to the question, but if someone reads this, I just want to point out that one should almost never implement a matrix as a ''vector of vectors''. The reason is that each row of the matrix gets stored in some random location on the heap. This means that matrix operations will do a lot of random memory accesses leading to cache misses, which slows down the implementation considerably.

In other words, if you care at all about performance, just allocate an array/std::array/std::vector of size rows * columns, then use wrapper functions that transforms a pair of integers to the corresponding element in the array. Unless you need to support things like returning references to rows of the matrix, then all of these options should work just fine.

2
  • @DOUGLASO.MOEN This depends entirely on the degree of contention for the heap. If you just allocated a vector of vectors straightforwardly, without anything else attempting an allocation (or releasing one), the buffers may well end up one right after the other.
    – defube
    Commented Jul 20, 2015 at 15:36
  • 1
    std::vector<std::array<T, RowSize>> is more convienent and just as fast as flat rows*columns with wrapper
    – JDiMatteo
    Commented Dec 4, 2015 at 19:45

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.