Somewhere in my brainstem a voice whispers:

In C++, an array does not need more memory than the number of elements need.

std::string str = "aabbcc"; 
std::array<std::string, 3> str_array = {"aa", "bb", "cc"}; 

Accordingly, both should have the same size, because (unlike in Java), there is no separate size field or similar. But I haven't found a reference.

Is this true? Under which circumstances is it not?

  • 2
    sizeof(std::string) is not 6. – NathanOliver Feb 27 '18 at 22:23
  • Nor 2......................... – LogicStuff Feb 27 '18 at 22:23
  • 1
    1 std::string can't be the same size as 3 std::strings – Kevin Feb 27 '18 at 22:24
  • 1
    I'm no biology expert, but I find it highly unlikely anyone's brainstem is capable of this level of abstract thought -- that's the part of our brains responsible for keeping our hearts, lungs, and other basic body functionality working. – MrEricSir Feb 27 '18 at 22:26
  • 1
    Don't confuse std::string and std::array with the old C-style types that C++ inherited. char s1[] = "aabbcc"; char *s2 = "aabbcc"; In these, s1 is 7 bytes (6 characters plus NUL terminator) while s2 is the size of a pointer. But std::string and std::array are smarter classes (e.g. std::string does not use NUL for terminator but keeps a separate length), so they have different implementations than the old types. – Dave Feb 27 '18 at 22:39

In C++, an array does not need more memory than the number of elements need.

This is true. A raw array has a size equal to the size of it's element type times the number of elements. So

int array[10];

has a size of sizeof(int) * std::size(array). std::array is the same but it is allowed t have padding so

std::array<int, 10> array;

has a size of sizeof(int) * std::size(array) + P where P is some integer amount of padding.

Your example though isn't quite the same thing. A std::string is a container. It has it's own size that is separate of what it contains. So sizeof(std::string) will always be the same thing regardless of how many characters are in the string. So ignoring short string optimization

std::string str = "aabbcc"; 

takes of sizeof(std::string) plus however much the string allocated for the underlying c-string. That is not the same value as

std::array<std::string, 3> str_array = {"aa", "bb", "cc"};

Since you now have 3 * sizeof(std::string) plus whatever each string allocated.

  • sizeof(std::string) may differ between SSO version and non-SSO. – Poeta Kodu Feb 27 '18 at 22:34
  • 1
    Last time I checked (and it was years ago) std::array was allowed to have some padding at the end. – juanchopanza Feb 27 '18 at 22:34
  • @juanchopanza and it is still allowed. – Poeta Kodu Feb 27 '18 at 22:35
  • @juanchopanza It is required to be an aggregate so I'm not sure if that still allows it or not. – NathanOliver Feb 27 '18 at 22:36
  • 1
    @juanchopanza Updated to include there could be some padding. – NathanOliver Feb 27 '18 at 22:40

Storing strings in any language is more complicated than you think. A C++ std::string must provide you contiguous storage for the contents. Apart from that, std::string can hold more things, like pointer/iterator to the last character, number of characters in it, etc. std::string::size is required to be O(1), so it must store more information than just a buffer. Also, most standard library implementations provide SSO (small string optimization). When SSO is enabled, std::string allocates a small buffer, to avoid unneccessary dynamic allocations. You can also reserve more memory than you need. Lets say, you need to collect 800-1000 characters in loop. You can do it like this:

std::string str;
    str += some_character;

But this will cause unneccessary memory allocations and deallocations. If you can estimate number of characters you want to store, you should reserve memory.

std::string str;

Then, you can always shrink_to_fit, to save memory:


There are also other things you must be aware of:

  • reserve increases capacity, but size stays the same. It means, that std::string must also store (or be able to calculate) for how many more characters buffer capacity allows.
  • string literals are null terminated
  • std::basic_string::c_str must return null terminated array of characters, so it is possible that std::string also contains null terminator (unluckily I am not sure how it is done)
  • there are more encodings and characters sets - ASCII is just one of them. UTF-8 and UTF-16 encoded strings may need to use few stored elements to add up to one code point, but this is more complicated.
  • Some? I guess there might exist a std library that does not do SSO currently. Some obscure embedded one? – Yakk - Adam Nevraumont Feb 27 '18 at 22:44
  • Well, I don't know. I did not want to mislead. You are right, let me change it. – Poeta Kodu Feb 27 '18 at 22:45

Accordingly, both should have the same size (e.g. 6 bytes),

Not a correct deduction.

The memory used by a std::string, if you want to call its size, consists of at least a pointer and the memory allocated to hold the data.

The memory allocated to hold the data can also include the space required to hold the terminating null character.


std::string s = "aabbcc";
std::string a = "aa";
std::string b = "bb";
std::string c = "cc";

mem(s) != mem(a) + mem(b) + mem(c)

Virtually every string can hold following info:

  • The size of the string i.e. num of chars it contains.

  • The capacity of memory holding the string's chars.

  • The value of the string.

Additionally it may also hold:

  • A copy of it's allocator and reference count for the value.

They don’t have the same size. Strings are saved null-terminated, giving you an extra byte for each string.

  • Null terminators isn't the half of it. You're forgetting the overhead of std::string itself. – Fred Larson Feb 27 '18 at 22:26

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