For example, I have a std::map with known sizeof(A) and sizeof(B), while map has N entries inside. How would you estimate its memory usage? I'd say it's something like

(sizeof(A) + sizeof(B)) * N * factor

But what is the factor? Different formula maybe?

Maybe it's easier to ask for upper bound?

  • 2
    Just to be clear, it is std::map<A, B>, right? – the swine Sep 21 '14 at 15:55

The estimate would be closer to


There is an overhead for each element you add, and there is also a fixed overhead for maintaining the data structure used for the data structure storing the map. This is typically a binary tree, such as a Red-Black Tree. For instance, in the GCC C++ STL implementation ELEMENT_OVERHEAD would be sizeof(_Rb_tree_node_base) and CONTAINER_OVERHEAD would be sizeof(_Rb_tree). To the above figure you should also add the overhead of memory management structures used for storing the map's elements.

It's probably easier to arrive at an estimate by measuring your code's memory consumption for various large collections.

  • While i totally agree with you, i'd like to have some upper bound without knowing internal STL struct sizes. – Drakosha Apr 6 '09 at 10:02
  • Are there not going to be N tree nodes? – Martin York Apr 6 '09 at 15:41
  • I disagree with this estimate, generally leaf nodes have the same size as non leaf nodes, so the '+ TREE_NODE_SIZE * log2(N)' part is not accurate. – Don Neufeld Apr 6 '09 at 19:25
  • 2
    For MSVC (VS2010), I found the corresponding node construct in file xtree::class _Tree_nod<Traits>::struct _Node. A Node contains 3 _NodePtrs (left, right, parent -> 12 / 24 byte on 32/64 bit systems) plus 2 chars (_Color and _Isnil) in addition to a value_type (which is std::pair<key, value>). This leaves me with an element overhead of 14/26 bytes per map entry. – Daniel Aug 31 '18 at 7:38
  • @Diomidis, is there a possibility to get the sizeof(_Rb_tree)? I get "missing template arguments" error...thanks – Taw Nov 25 '18 at 17:35

You could use MemTrack, by Curtis Bartley. It's a memory allocator that replaces the default one and can track memory usage down to the type of allocation.

An example of output:

Memory Usage Statistics

allocated type                        blocks          bytes  
--------------                        ------          -----  
struct FHRDocPath::IndexedRec          11031  13.7% 2756600  45.8%
class FHRDocPath                       10734  13.3%  772848  12.8%
class FHRDocElemPropLst                13132  16.3%  420224   7.0%
struct FHRDocVDict::IndexedRec          3595   4.5%  370336   6.2%
struct FHRDocMDict::IndexedRec         13368  16.6%  208200   3.5%
class FHRDocObject *                      36   0.0%  172836   2.9%
struct FHRDocData::IndexedRec            890   1.1%  159880   2.7%
struct FHRDocLineTable::IndexedRec       408   0.5%  152824   2.5%
struct FHRDocMList::IndexedRec          2656   3.3%  119168   2.0%
class FHRDocMList                       1964   2.4%   62848   1.0%
class FHRDocVMpObj                      2096   2.6%   58688   1.0%
class FHRDocProcessColor                1259   1.6%   50360   0.8%
struct FHRDocTextBlok::IndexedRec        680   0.8%   48756   0.8%
class FHRDocUString                     1800   2.2%   43200   0.7%
class FHRDocGroup                        684   0.8%   41040   0.7%
class FHRDocObject * (__cdecl*)(void)     36   0.0%   39928   0.7%
class FHRDocXform                        516   0.6%   35088   0.6%
class FHRDocTextColumn                   403   0.5%   33852   0.6%
class FHRDocTString                      407   0.5%   29304   0.5%
struct FHRDocUString::IndexedRec        1800   2.2%   27904   0.5%

If you really want to know the runtime memory footprint, use a custom allocator and pass it in when creating the map. See Josuttis' book and this page of his (for a custom allocator).

Maybe it's easier to ask for upper bound?

The upper bound will depend on the exact implementation (e.g. the particular variant of balanced tree used). Maybe, you can tell us why you need this information so we can help better?

  • Thats the only way to get an accurate number. – David Lehavi Apr 6 '09 at 8:32
  • Can STL internal allocator supply information how much memory totally is used by STL? – Drakosha Apr 6 '09 at 10:04
  • @Drakosha: No, that allocator is not meant to do this. Which is why you need to create a custom one that will report whatever you want it to. – dirkgently Apr 6 '09 at 13:18
  • 2
    Stephan T. Lavavej also has a nice article on custom allocators: blogs.msdn.com/vcblog/archive/2008/08/28/the-mallocator.aspx Read the comments for a bit of trivia about <cheader> vs. <header.h> use. Now I can feel justified in my continued use of the .h variant of C headers in my C++ code! – Michael Burr Apr 6 '09 at 19:13
  • @Michael: Why headers all of sudden? Some context will be of help! – dirkgently Apr 6 '09 at 19:50

I recently needed to answer this question for myself, and simply wrote a small benchmark program using std::map I compiled under MSVC 2012 in 64-bit mode.

A map with 150 million nodes soaked up ~ 15GB, which implies the 8 byte L, 8 byte R, 8 byte int key, and 8 byte datum, totaling 32 bytes, soaked up about 2/3rds of the map's memory for internal nodes, leaving 1/3rd for leaves.

Personally, I found this to be surprisingly poor memory efficiency, but it is what it is.

Hope this makes for a handy rule-of-thumb.

PS: The overhead of a std::map is that of a single node's size AFAICT.

  • 6
    In you need better memory efficiency, you could go with code.google.com/p/cpp-btree – Drakosha Sep 9 '13 at 13:24
  • 1
    See my comment in Diomidis Spinellis answer. I found element overheads per map entry of 3 pointers + 2 chars -> 14/26 bytes on 32/64 bit in addition to the key value pair. The fraction of overhead will of course depend on the sizes of your keys and values. – Daniel Aug 31 '18 at 7:43

The formula is more like:

(sizeof(A) + sizeof(B) + factor) * N

where factor is the per entry overhead. C++ maps are typically implemented as red-black trees. These are binary trees, so there will be at least two pointers for the left/right nodes. There will also be some implementation stuff - probably a parent pointer and a "colour" indicator, so factor may be something like

(sizeof( RBNode *) * 3 + 1) / 2

However, all this is highly implementation dependent - to find out for sure you really need to examine the code for your own library implementation.


The size of the map really depends on the implementation of the map. You might have different sizes on different compilers/platforms, depending on which STL implementation they are providing.

Why do you need this size?

  • Ok, g++. I need this size to know hom much entries i can hold in memory before i start swapping. I need upper bound. – Drakosha Apr 6 '09 at 10:05
  • If you need the upper bound, I suggest to take a look to the implementation of the map, to see how a map node object is implemented and to consider the size of the members of the map node as extra to the size of the key and element. Be aware that this approach is platform and compiler specific. – Cătălin Pitiș Apr 6 '09 at 12:35
  • Disable the virtual system, and write a benchmark to slowly increase the size of a test map. You'll know soon enough by watching Windows Task Manager's Peak Working Set metric when you run out of memory. I guess some people would just rather discuss something to death instead of design a simple test and know for certain. These people add nothing to the world, and soak up a lot of time and brain-power because they can't stop to think about how to construct a good test of the variables in question. Arrrgggh – user1899861 Sep 9 '13 at 5:49

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