In one time-critical part of the program there is a member of the class that looks like that: std::vector m_vLinks; During profiling I noticed that about 99.98% of executions this vector holds only 0 or 1 items. However in very rarely cases it might hold more. This vector is definitely a bottleneck according to profiler, so I'm thinking about following optimization:

  1. Craft a hand-made class with vector-like interface
  2. This class will hold true size, one item and optional pointer to the vector
  3. In this case when vector holds 1 item there won't be any dynamic memory allocations, and also accessing this item will be (a bit) faster due to removing of one indirection.
  4. When we need to hold more data vector is dynamically allocated
  5. Of course this vector won't provide one memory block holding all items (not needed here), and also some operations will be more complex

Before starting to prototype this thing to see if it helps, I wonder if anyone encountered custom containers with similar functionality in some 3rd-party libraries?

I already thought about boost::array, but don't want size limit that it imposes

  • 1
    Which operations exactly take most of the time in your scenario?
    – sharptooth
    Feb 21, 2012 at 14:27
  • is vector a bottleneck because you frequently create new ones? In that case I doubt your optimization will help much... Feb 21, 2012 at 14:28
  • 3
  • 7
    You could use a custom allocator to achieve this directly with std::vector. Check out Howard Hinnants stack_alloc: home.roadrunner.com/~hinnant/stack_alloc.html Feb 21, 2012 at 14:45
  • 3
    @Fahrenheit2539: "This vector is definitely a bottleneck according to profiler" - doing what with the vector is definitely a bottleneck? If it's anything other than, "increasing its size from 0 to 1" or "copying it when its size is 1", then I don't see why your change would make a difference. Feb 21, 2012 at 15:12

4 Answers 4


LLVM has a class for that called SmallVector.

  • 2
    Of course, the one question: is it faster, really ? There is quite a heavy-weight hierarchy and I do wonder whether it can manage the speed of vector or not. Feb 21, 2012 at 14:58
  • 3
    In general, hierarchies don't make code slow. Compilers see right through that. In particular, if you see stuff like is_pod<T> in a hierarchy, you know that's compile-time computing.
    – MSalters
    Feb 21, 2012 at 15:01
  • @MSalters: Sorry if it didn't sound right. What I meant is that there is way too much code for me to eyeball whether or not it will be faster than vector. Feb 21, 2012 at 15:07
  • 2
    @MatthieuM. -- The following program runs in about 4.5 seconds for me: pastebin.com/Vmr47x0b -- When I switch it to use llvm::SmallVector, it goes to about 1.5 seconds. Feb 21, 2012 at 15:24

In a non-time-critical part of your code, perform: m_vLinks.reserve(1);. That way, in the time-critical part, there will typically be no dynamic allocation.


My first attempt would be to optimize the memory allocator. Naive malloc implementations are not too efficient, you may want to try tcmalloc or jemalloc.

My second attempt would be to change the allocator. Howard Hinnant has demonstrated how to use a stateful allocator that has some memory preallocated on the stack. This is only Standard compliant in C++11, but may already be supported.

My third attempt would be to change the code and pre-allocate the memory if possible. Instead of building the vector anew each time, you could keep it around: its capacity will not diminish and so subsequent uses won't allocate memory.

There are few chances that a homebrew implementation would match the speed of the std::vector<T> classes, as many of its methods have been tuned for maximum performance.


I generally use std::list for these cases. The O(N) operations in std::list don't hurt me when N==1.

  • 3
    I suppose there is at least 1 dynamic memory allocation when item is added into the list (even if it is the first item). I needed the solution that could hold 1 item without any dynamic allocations
    – Alex Z
    Feb 21, 2012 at 15:01
  • True, but that dynamic allocation is always the same size (single node), unlike std::vector, and the node pointer is always dereferenced. That's actually not as bad as you'd think, on modern hardware and with modern allocators.
    – MSalters
    Feb 21, 2012 at 15:06
  • The dynamic allocation is solved by the pool he's using. However, that leads to poor locality.
    – phkahler
    Feb 21, 2012 at 15:08

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