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I have 2 C++ classes I1, I2, implementing integer arithmetics; each one is optimized for the integer size it can handle, each one taking a specific memory size.

I would like to have some high level Integer class that encapsulates I1, I2 and that I could configure at runtime (with some static method) to make it acts as I1 or I2. The underlying idea is to let clients using Integer instead of I1 or I2, according to the required arithmetics precision she/he defines at runtime. Note that the runtime consideration is crucial for me.

A "natural" choice would be to use dynamic allocation BUT I have a lot of instances to handle (with a lot of temporary objects) and dynamic allocation becomes time expensive.

I had a look at boost::variant with I1, I2, and it could fit my needs. However, it seems that the variant has the size max(sizeof(I1),sizeof(I2)), which is an issue for me because I need to dump the instances in file system with the appropriate size.

My question is so: is there any possibility to define such an Integer class:

  • using I1 or I2 implementation after some runtime configuration
  • using stack instead of heap (no dynamic allocation)
  • using just the memory needed (sizeof(I1) if I1 is used, sizeof(I2) if I2 is used) and not the maximum of the two sizes.
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Does this new Integer class plan to change its inner behavior (i.e switching from I1 to I2) in cases like overflows? –  diegoperini Oct 3 '13 at 17:31
    
No, it should be configured only once at startup after reading some information in a file (this is the reason why I can't decide statically if I use I1 or I2). –  edrezen Oct 4 '13 at 7:51
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2 Answers

You could use boost::variant. When dumpping to the file system, instead of the variant you convert it to the contained type (either i1 or i2) and dump the result. This can be done through a visitor.

Update: After edrezen's clarification (in a comment below).

From what I understand you want a stack-based (since dynamic memory allocations are to be avoided) discriminated union container (like boost::variant) called Integer that can hold values of type either I1 or I2. In addition, if i is an Integer, then you want

  1. sizeof(i) == sizeof(I1) if i holds an I1 value; and
  2. sizeof(i) == sizeof(I2) if i holds an I2 value.

This is impossible because the size of a type is decided at compile time and cannot be changed at runtime.

The best you can have is what boost::variant gives, i.e., sizeof(I) == max(sizeof(I1), sizeof(I2)). You're probably worring too much with memory consumption and doing premature optimization. I would suggest you to go for boost::variant.

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It could work indeed for serialization, but to be more precise, the issue with boost::variant in my case is the memory usage since I can really have many, many instances in memory. Say for instance that I1 takes N bytes in memory and I2 takes 2N bytes. With boost::variant, even if I need the I1 value, I will have 2 times the memory actually needed because boost::variant takes the maximum of the two sizes, which is the size 2N of I2. –  edrezen Oct 4 '13 at 14:37
    
@edrezen: What you want seems impossible. (See the update.) –  Cassio Neri Oct 4 '13 at 15:36
    
You got the whole picture of the problem and I do agree that boost::variant sounds good. Nevertheless, memory consumption is really an issue and the whole available RAM may be needed. If the useful memory is reduced artificially by two, the execution time will double, which is not wanted because the algorithm takes a long time. As you said, I'm affraid it is impossible (at least with my knowledge), but I'm still trying to find some way to achieve it. –  edrezen Oct 4 '13 at 16:27
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I may have found some redesign choice that could work in my case. My performance issue (memory concerns and execution time) comes mainly because I want to use a generic integer class relying on one specific implementation throughout the code. In other words, I am trying to use the variant at a too low level.

Actually, my integer classes are used by an algorithm reified as a template class Algo<T>, the template T being the integer class I1 or I2.

I could use the boost::variant with the two types Algo<I1> and Algo<I2>:

  • from the client point of view, only the variant is seen, so the code is generic (except for the initialization of the variant); for instance, the execute method of the algorithm can be called through some variant visitor.
  • memory usage is optimal because there is no variant used at low level integer arithmetic
  • for the same reason, time execution is optimal because we don't have to suffer from the underlying switch (hardcoded inside the variant) several billions of times.

The only bad thing I can see is the need to define several variant types; actually, I have not only Algo<T>but also several other types depending on template T. For instance, I need some algorithm result type. This was the initial reason why I tried to have only one variant at a low level, but my performances concerns made me change my mind.

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