As known, if we push_back elements to the
std::vector<>, and if the whole memory allocated in the vector is occupied, then
std::vector<> reserves 2X of current size of memory (allocate new memory with 2X size), resize vector and copy old data to the new memory.
We can optimizing it, and Facebook done this in folly-library (FBVector is Facebook's drop-in implementation of std::vector. It has special optimizations for use with relocatable types and jemalloc https://github.com/facebook/folly/blob/master/folly/FBVector.h#L21 ).
vector<> does not have enough memory to push_back new element, then we allocate more memory but not in 2 times more (in a different number of times: 1.3 - 1.5 times)
The graphical solver below reveals that choosing k = 1.5 (blue line) allows memory reuse after 4 reallocations, choosing k = 1.45 (red line) allows memory reuse after 3 reallocations, and choosing k = 1.3 (black line) allows reuse after only 2 reallocations.
But why do we need to use
folly::fbvector<> instead of
std::vector<> with our custom allocator which using
VirtualAllocEx() (as shown here: For what do I need to use VirtualAlloc/VirtualAllocEx? ), or the same in linux https://stackoverflow.com/a/2782910/1558037 , where:
std::vector<>::reserve()- initially reserve large un-commited area of virtual address (allocate WMA, but doesn't allocate any PTE in PT), for example allocate initially 16 GB of virtual area and each time the lack of memory to commit memory (allocate PTEs - allocate physical area) equal 1 x SIZE of vector
std::vector<>::resize()- and then only commit a new batch of pages, allocate only new PTE in PT, without re-allocation of memory which already is used and without copying data from old memory to new
The advantages of this approach with large un-commited area over the
folly::vector<>: always we allocate only new part of memory and never copying old data.
The advantages of
folly::vector<> approach over the
std::vector<>: sometimes we do not need to allocate new memory, but copying the old data into the new memory should always.