Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

Sign up and start helping → Learn more about Documentation →

I am very new to the world of C++ programming, so sorry for my amatuerish question:

I get a large block of data stored in the main memory (1-D array), and I need to access some of the data there frequently, my way of doing this is:

float *x=new float[20];//array to store x;
int *indlistforx=new int[20];//array to store the index of x;
float *databank=new float[100000000];//a huge array to store data

/... fill data to databank.../

for (int i=0;i<N;i++)//where N is a very large number;
  /... write index to indlistforx.../
  getdatafromdatabank(x, indlistforx, databank);
  //Based on the index provided by indlistforx, read data from databank then pass them to x

  /...do something with x.../

Is there any efficient/fast way to access these data(the index for x are not aligned, and it is impossible to be aligned)?

Many thanks in advance!

share|improve this question
new float[100000000];? May you live in the 70's... – user529758 Oct 15 '12 at 21:58
I don't quite understand your question. Is some part of your code running too slowly? – Greg Hewgill Oct 15 '12 at 21:59
I don't get the question. What is x? – Claudix Oct 15 '12 at 22:01
@H2CO3: the data I handle is huge, which occupies roughly 20+ GB memory in double format, thats why I use f32 instead of double... – user0002128 Oct 15 '12 at 22:23
RAII generally offers advantages in terms of correctness and simplicity, but there shouldn't be any disadvantage in terms of performance – Useless Oct 15 '12 at 23:27

Since a float needs to be initialized, you really should use a std::vector<>, it is not slower, construct and fill like this:

std::vector< float > databank( 100000000, 0.0f );

There are a few options for speedup:

1) If there is a reasonably large key(index) reuse, then you can use a caching or memorization strategy of some sort. See http://www.boost.org/doc/libs/1_51_0/libs/flyweight/doc/index.html for an example.

2) You can split the processing into multiple threads, using say std::async().

3) Make sure your compiler has simd instructions (sse on x86) turned on and is using them. If not force the use of simd by using compiler intrinsics. This will allow a near 4x improvement.

share|improve this answer
Many thanks, I will try your suggestions, as for SIMD, yes, my program is compiled with AVX option. – user0002128 Oct 15 '12 at 23:11
I'm not going to downvote, but this answer is essentially incorrect. Switching to vectors is not going to help. The only difference between std::vector<float> and a float* is safety. Speed? No. Vectors are just an RAII-safe wrapper around a raw pointer. The chief culprit is the random access; switching to a vector won't change that. What will change that is to get rid of that random access. – David Hammen Oct 16 '12 at 12:20

You haven't really shown how you're accessing your databank, so this is all very speculative:

  • is indlistforx a list of 20 indices into the databank, so you're doing 20 random accesses?

    • what is the stride in these indices: are they consecutive, or close together, or random?
    • if they're consecutive or close together, sorting them may help (so you're reading in ascending order to improve prefetch, and grouping reads from the same cache line together)
  • how much do different groups of 20 indices jump around? can they overlap?

    • if they can't overlap, so your databank is effectively partitioned into some chunk size, then handling each partition on a different processor might increase the amount of effective cache you can use (if you have multiple processors)
    • if requests can overlap running them concurrently can still work if the databank is read-only. If anything writes to the databank, this becomes a recipe for cache thrashing
  • can you reorder your accesses at a higher level to get better cache behaviour: more sequential, better spatial or temporal locality of reference?

    • this is essentially the same as my first suggestion, but above the level of a single indlistforx request
    • similarly, consider reordering them to effectively partition the databank and try the multi-processor idea

Without seeing all the code (or a representative sample, and I understand even that may be too large) it's hard to go into any more detail.

However, there is one general technique that might work ... it might also be so heavyweight that the implementation cost outweighs the savings.

  • make your getfromdatabank return a future/promise/whatever, rather than completing synchronously (or a vector of 20 futures, if that's not too fine-grained)
  • try to dispatch lots of these asynchronous requests in parallel, either in separate threads (where accessing the futures would be a blocking operation) or using an event loop to handle completions with something like explicit co-routines
  • have a dedicated thread aggregate all the databank accesses from multiple requests, and reorder them for better cache performance

This can only work if the extra synchronization overhead is dominated by improved read performance, and if you can usefully run many queries in parallel.

share|improve this answer
+1. This random access is the real culprit. – David Hammen Oct 15 '12 at 23:56
Thanks, in my case, it is random-access of data, but without over-lap. – user0002128 Oct 16 '12 at 1:23
Many thanks for your suggestion, yes, the reason why I cannot post the codes is because I use simd intrinsic functions and CUDA codes extensively so the codes are too long and most part of them are irrelevant to random memory-accessing. – user0002128 Oct 18 '12 at 4:39

The problem isn't how you are representing your databank. The problem is how you are using it. Randomly accessing widely separated pieces of your databank in short order is going to kill your performance. Your getdatafromdatabank(x, indlistforx, databank) with that indlistforx almost guarantees poor performance. The random access enabled by that indlistforx comes with a significant performance penalty. If that random access absolutely necessary because how the algorithms that use your databank work, that's just a price you will have to pay.

You'll get much better performance if you can modify your algorithms so that they access contiguous chunks of memory in your databank. Change getdatafromdatabank so that you specify the first index only (the index of the element that you want loaded into x[0]) rather than an array 20 indices.

Is there a reason that x is sized at 20? You'll get best performance if you just barely manage to keep the output x array and the relevant chunk of the databank in level 1 cache. Performance will start to decrease, and may decrease significantly, if the size of x increases beyond this optimal size.

share|improve this answer
I have to use random access, I can re-arrange the databank to allow chunk-based access, however that will reduce the performance of other part of the codes, and the trade-off isnt pretty(actually the exact reason why I have to let it access the databank randomly is to enable the other part of my codes access the data "chunkly"), thats why I have to stick to random-access of the large chunk of data, I just want to know if there are any ways to improve the performance of random-access, I wonder if multi-threading will help much? – user0002128 Oct 16 '12 at 1:23

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

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