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Suppose I have a c++ code with many small functions, in each of which i will typically need a matrix float M1(n,p) with n,p known at run-time to contain the results of intermediate computations (no need to initialize M1, just to declare it because each function will just overwrite over all rows of M1).

Part of the reason for this is that each function works on an original data matrix that it can't modify, so many operations (sorting, de-meaning, sphering) need to be done on "elsewhere".

Is it better practice to create a temporary M1(n,p) within each function, or rather once and for all in the main() and pass it to each function as a sort of bucket that each function can use as scrap space?

n and p are often moderately large [10^2-10^4] for n and [5-100] for p.

(originally posted at the codereview stackexchange but moved here).

Best,

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depends. memory allocation is expensive. start with local allocs and modify if allocs are too costly –  Anycorn Mar 2 '12 at 7:41
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@Anycorn memory allocation is probably less expensive than accessing 500 or more values, and definitely less expensive than accessing a million values. –  James Kanze Mar 2 '12 at 9:05
    
@JamesKanze +1 the relative efficiency of the heap allocation is generally going to be trivial compared to these operations. I'm thinking of editing my post to avoid suggesting the optimization route completely. –  stinky472 Mar 2 '12 at 9:35
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@stinky472 Yes. A general rule is that it is the small allocations which impact performance. The cost of allocating something like 3 or 4 double can easily dominate performance; the cost of allocating a million double is negligible if you actually access all of them. (Although many systems have special, optimized allocators for small blocks, in order to minimize this effect---and to avoid excessive fragmentation.) –  James Kanze Mar 2 '12 at 10:00
    
@JamesKanze totally agreed. I ended up putting a major caveat with a horizontal separator to try to discourage that route, at least without profiling first. I've had to optimize heap allocations for performance-critical areas before, but only with linked structures involved (millions of teeny nodes, not giant contiguous blocks). –  stinky472 Mar 2 '12 at 10:08
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4 Answers

up vote 2 down vote accepted
  1. heap allocations are indeed, quite expensive.
  2. premature optimization is bad, but if your library is quite general and the matrices are huge, it may not be premature to seek an efficient design. After all, you don't want to modify your design after you accumulated many dependencies to it.
  3. there are various levels in which you can tackle this problem. You can, for example, avoid the heap allocation expense by tackling it at the memory allocator level (per-thread memory pool, e.g.)
  4. while heap allocation is expensive, you are creating one giant matrix only to do some rather expensive operations on the matrices (typically linear complexity or worse). Relatively speaking, allocating a matrix on the free store may not be that expensive compared to what you are inevitably going to have to do with it subsequently, so it may actually be quite cheap in comparison to the overall logic of a function like sorting.

I recommend you write the code naturally, taking into account #3 as a future possibility. That is, don't take in references to matrix buffers for intermediary computations to accelerate the creation of temporaries. Make the temporaries and return them by value. Correctness and good, clear interfaces come first.

Mostly the goal here is to separate the creational policy of a matrix (via allocator or other means) which gives you that breathing room to optimize as an afterthought without changing too much existing code. If you can do it by modifying only the implementation details of the functions involved or, better yet, modifying only the implementation of your matrix class, then you're really well off because then you're free to optimize without changing the design, and any design which allows that is generally going to be complete from an efficiency standpoint.


WARNING: The following is only intended if you really want to squeeze the most out of every cycle. It is essential to understand #4 and also get yourself a good profiler. It's also worth noting that you'll probably do better by optimizing memory access patterns for these matrix algorithms than trying to optimize away the heap allocation.


If you need to optimize the memory allocation, consider optimizing it with something general like a per-thread memory pool. You could make your matrix take in an optional allocator, for instance, but I emphasize optional here and I'd also emphasize correctness first with a trivial allocator implementation.

In other words:

Is it better practice to declare M1(n,p) within each function, or rather once and for all in the main() and pass it to each function as a sort of bucket that each function can use as scrap space.

Go ahead and create M1 as a temporary in each function. Try to avoid requiring the client to make some matrix that has no meaning to him/her only to compute intermediary results. That would be exposing an optimization detail which is something we should strive not to do when designing interfaces (hide all details that clients should not have to know about).

Instead, focus on more general concepts if you absolutely want that option to accelerate the creation of these temporaries, like an optional allocator. This fits in with practical designs like with std::set:

std::set<int, std::less<int>, MyFastAllocator<int>> s; // <-- okay

Even though most people just do:

std::set<int> s;

In your case, it might simply be: M1 my_matrix(n, p, alloc);

It's a subtle difference, but an allocator is a much more general concept we can use than a cached matrix which otherwise has no meaning to the client except that it's some kind of cache that your functions require to help them compute results faster. Note that it doesn't have to be a general allocator. It could just be your preallocated matrix buffer passed in to a matrix constructor, but conceptually it might be good to separate it out merely for the fact that it is something a bit more opaque to clients.

Additionally, constructing this temporary matrix object would also require care not to share it across threads. That's another reason you probably want to generalize the concept a bit if you do go the optimization route, as something a bit more general like a matrix allocator can take into account thread safety or at the very least emphasize more by design that a separate allocator should be created per thread, but a raw matrix object probably cannot.


The above is only useful if you really care about the quality of your interfaces first and foremost. If not, I'd recommend going with Matthieu's advice as it is much simpler than creating an allocator, but both of us emphasize making the accelerated version optional.

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Everyone always thinks they can beat the standard allocator. You don't think the implementors of std::allocator would have thought of that? –  CashCow Mar 2 '12 at 8:28
    
@CashCow the standard allocator is very general. For example, it assumes we free allocated blocks immediately. I actually made a simple stack-based memory pool allocator. It allocates memory at an average of 4 cycles as opposed to the standard allocator which tends to take about 400 on our platforms (common case comes down to incrementing one pointer). My special trick: I don't free memory in deallocate! Normally it's a leak fest, except there is a purge function on the allocator.. but that makes it dangerous to use, and we only use it in the most performance-critical parts of our raytracer. –  stinky472 Mar 2 '12 at 8:35
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@CashCow so to match both the generality of the standard allocator and beat its efficiency, I'd say that's an impractical goal for sure. But if we make some assumptions at the risk of reducing generality, safety, or fragmentation concerns, then we can easily beat its speed, but at some cost to one or more of these areas. –  stinky472 Mar 2 '12 at 8:37
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In some ways, yes, a generic allocator doesn't know how you intend to use it, so sometimes you can optimise for your own particular usage. When it comes to std::set, the implementor may choose to pre-allocate a number of nodes rather than allocate in ones, knowing that it is likely to be storing lots of small objects. –  CashCow Mar 2 '12 at 9:55
    
@CashCow we did exactly that sort of thing but based on the assumption that we're creating things like set without the need to ever remove elements (until the whole allocator is destroyed). So the allocator was a simple stack, only pushing by incrementing a stack pointer for the most part (until it exceeded capacity, at which point it'd create a new block). and never popping or removing anything from the middle until the whole allocator was destroyed. Naturally that is very unsafe(requires allocator to be destroyed before set) and very special-purpose, but it did the trick (4 cycles vs. 400). –  stinky472 Mar 2 '12 at 10:00
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Do not use premature optimisation. Create something that works properly and well and optimise later if it is shown to be slow.

(By the way I don't think stackoverflow is the correct place for it either).

In reality if you want to speed up your application operating on large matrices, using concurrency would be your solution. And if you are using concurrency, you are likely to get into far more trouble if you have one big global matrix.

Essentially it means you can never have more than one calculation happening at a time, even if you have the memory for it.

The design of your matrix needs to be optimal. We would have to look at this design.

I would therefore generally say in your code, no, do NOT create one big global matrix because it sounds wrong for what you want to do with it.

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:> thanks for the advice. In this case, the main function has to be repeated on a large number of independent input matrices X_{1}...X_{k}'s, so the concurrency is done at an "higher" level than the function i'm writing, which is for a single one of these X_{k} [I hope it is clear -- if not let me know and i rephrase it]. –  user189035 Mar 2 '12 at 9:30
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well yes of course you can achieve concurrency by having multiple instances of your process running, just that you shouldn't rule out having it within one process by giving yourself a design that optimises in the wrong area. –  CashCow Mar 2 '12 at 9:52
    
yes i understood your point and it is in general totally valid. I wanted to give some context specific information. –  user189035 Mar 2 '12 at 10:09
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First try to define the matrix inside the function. That is definitely the better design choice. But if you get performance losses you can't affort, I think the "passing buffer per reference" is ok, as long as you keep in mind that the functions aren't thread safe anymore. If at any point you use threads, each thread needs it own buffer.

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There are advantages in terms of performance in requiring an externally supplied buffer, especially when you are required to chain the functions that make use of it.

However, from a user point of view, it can soon get annoying.

I have often found that it's simple enough in C++ to get the best of both worlds by simply offerring both ways:

int compute(Matrix const& argument, Matrix& buffer);

inline int compute(Matrix const& argument) {
  Matrix buffer(argument.width, argument.height);
  return compute(argument, buffer);
}

This very simple wrapping means that the code is written once, and two slightly different interfaces are presented.

The more involved api (taking a buffer) is also slightly less safe as the buffer must respect some size constraints wrt the argument so you might want to further insulate the fast api (for example behind a namespace) as to encourage users to use the slower but safer interface first, and only try out the fast one when it's proven necessary.

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