It had been my understanding that copy-on-write is not a viable way to implement a conforming std::string in C++11, but when it came up in discussion recently I found myself unable to directly support that statement.

Am I correct that C++11 does not admit COW based implementations of std::string?

If so, is this restriction explicitly stated somewhere in the new standard (where)?

Or is this restriction implied, in the sense that it is the combined effect of the new requirements on std::string that precludes a COW based implementation of std::string. In this case, I'd be interested in a chapter and verse style derivation of 'C++11 effectively prohibits COW based std::string implementations'.


7 Answers 7


It's not allowed, because as per the standard 21.4.1 p6, invalidation of iterators/references is only allowed for

— as an argument to any standard library function taking a reference to non-const basic_string as an argument.

— Calling non-const member functions, except operator[], at, front, back, begin, rbegin, end, and rend.

For a COW string, calling non-const operator[] would require making a copy (and invalidating references), which is disallowed by the paragraph above. Hence, it's no longer legal to have a COW string in C++11.

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    Some rationale: N2534
    – M.M
    Dec 18, 2014 at 3:54
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    @Cheersandhth.-Alf: The logic can be seen in the following if COW were allowed: std::string a("something"); char& c1 = a[0]; std::string b(a); char& c2 = a[1]; c1 is a reference to a. You then "copy" a. Then, when you attempt to take the reference the second time, it has to make a copy to get a non-const reference since there are two strings that point to the same buffer. This would have to invalidate the first reference taken, and is against the section quoted above.
    – Dave S
    Dec 18, 2014 at 12:05
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    @Cheersandhth.-Alf, according to this, at least GCC's COW implementation does do exactly what DaveS is saying. So at least that style of COW is prohibited by the standard. Jan 18, 2015 at 17:48
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    @Alf: This answer argues that non-const operator[] (1) must make a copy and that (2) it is illegal for it to do so. Which of those two points do you disagree with? Looking at your first comment, it seems that an implementation could share the string, at least under this requirement, up until the time it is accessed, but that both read and write accesses would need to unshare it. Is that your reasoning?
    – Ben Voigt
    Mar 5, 2015 at 15:00
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    @Cheersandhth.-Alf, I have added my own answer, which simply expands on the correct answer by Dave S above. Maybe if you now re-read my comments above you will see that I was asking you to provide some justification for your own seemingly extraordinary claims such as "On the other hand, the view that that bug means something about the formal, that someone else has claimed, is nonsense." (that was my own view that you labelled as nonsense, yet I'm the one accused of ad hominem attacks and getting personal when I use the same word! How offensive!) Mar 22, 2015 at 21:10

The answers by Dave S and gbjbaanb are correct. (And Luc Danton's is correct too, although it's more a side-effect of forbidding COW strings rather than the original rule that forbids it.)

But to clear up some confusion, I'm going to add some further exposition. Various comments link to a comment of mine on the GCC bugzilla which gives the following example:

std::string s("str");
const char* p = s.data();
    std::string s2(s);
    (void) s[0];
std::cout << *p << '\n';  // p is dangling

The point of that example is to demonstrate why GCC's reference counted (COW) string is not valid in C++11. The C++11 standard requires this code to work correctly. Nothing in the code permits the p to be invalidated in C++11.

Using GCC's old reference-counted std::string implementation, that code has undefined behaviour, because p is invalidated, becoming a dangling pointer. (What happens is that when s2 is constructed it shares the data with s, but obtaining a non-const reference via s[0] requires the data to be unshared, so s does a "copy on write" because the reference s[0] could potentially be used to write into s, then s2 goes out of scope, destroying the array pointed to by p).

The C++03 standard explicitly permits that behaviour in 21.3 [lib.basic.string] p5 where it says that subsequent to a call to data() the first call to operator[]() may invalidate pointers, references and iterators. So GCC's COW string was a valid C++03 implementation.

The C++11 standard no longer permits that behaviour, because no call to operator[]() may invalidate pointers, references or iterators, irrespective of whether they follow a call to data().

So the example above must work in C++11, but does not work with libstdc++'s kind of COW string, therefore that kind of COW string is not permitted in C++11.

  • 1
    Let us continue this discussion in chat. Mar 23, 2015 at 16:24
  • Good observation, those are new C++11 requirements, and they can't be met by a COW implementation. In addition to noexcept can't be met. Re “OK to be wrong”, will you delete this answer? When I get the time (sorry, I've used far too much already) I'll update my answer with both your observations: that (1) C++03 made a special exemption for first time calls, where e.g. s[i] can invalidate a pointer obtained from s.data(), even though in general client code can't know whether a call is first time or not, and (2) new O(1) complexity requirements on string operations, where C++03 had none. Mar 23, 2015 at 20:58
  • @JonathanWakely: I can imagine some cases where a string which shares backing stores until they're accessed could be useful. For example, concatenating two strings with sharable backing stores could yield a new string object that holds references to both backing stores; concatenating that to something else could build up a tree. If intermediate strings are not used for any purpose except as fodder for future concatenations, such an approach could seem useful. It wouldn't quite be "copy-on-write" in the usual sense, but the idea of sharing data as long as practical would remain.
    – supercat
    Nov 12, 2015 at 19:37
  • @supercat, that would add a lot of overhead but would pessimize all uses that don't involve concatenating strings. Also see the point I made at stackoverflow.com/questions/12199710/… Nov 13, 2015 at 8:31
  • −1 "The answers by Dave S and gbjbaanb are correct." is a falsehood. In particular, Dave's assertion is irrational, with language that has the look & feel of logic, but isn't. The conclusion at the end in this answer, that the buggy COW in g++'s libstdc++ isn't permitted, is OK. Jul 28, 2016 at 21:30

It is, CoW is an acceptable mechanism for making faster strings... but...

it makes multithreading code slower (all that locking to check if you're the only one writing kills performance when using a lot of strings). This was the main reason CoW was killed off years ago.

The other reasons are that the [] operator will return you the string data, without any protection for you to overwrite a string someone else expects to be unchanging. The same applies to c_str() and data().

Quick google says that the multithreading is basically the reason it was effectively disallowed (not explicitly).

The proposal says :


We propose to make all iterator and element access operations safely concurrently executable.

We are increasing the stability of operations even in sequential code.

This change effectively disallows copy-on-write implementations.

followed by

The largest potential loss in performance due to a switch away from copy-on-write implementations is the increased consumption of memory for applications with very large read-mostly strings. However, we believe that for those applications ropes are a better technical solution, and recommend a rope proposal be considered for inclusion in Library TR2.

Ropes are part of STLPort and SGIs STL.

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    The operator[] issue isn't really a problem. The const variant does offer protection, and the non-const variant always has the option of doing the CoW at that time (or being really crazy and setting up a page fault to trigger it). Sep 30, 2014 at 6:48
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    it's just silly that a std::cow_string class wasn't included, with lock_buffer(), etc. there are lots of times i know threading isn't an issue. more often than not, actually. Apr 16, 2015 at 20:47

Is COW basic_string prohibited in C++11 and later?


Am I correct that C++11 does not admit COW based implementations of std::string?



If so, is this restriction explicitly stated somewhere in the new standard (where)?

Almost directly, by requirements of constant complexity for a number of operations that would require O(n) physical copying of the string data in a COW implementation.

For example, for the member functions

auto operator[](size_type pos) const -> const_reference;
auto operator[](size_type pos) -> reference;

… which in a COW implementation would ¹both trigger string data copying to un-share the string value, the C++11 standard requires

C++11 §21.4.5/4:

Complexity: constant time.

… which rules out such data copying, and hence, COW.

C++03 supported COW implementations by not having these constant complexity requirements, and by, under certain restrictive conditions, allowing calls to operator[](), at(), begin(), rbegin(), end(), or rend() to invalidate references, pointers and iterators referring to the string items, i.e. to possibly incur a COW data copying. This support was removed in C++11.

Is COW also prohibited via the C++11 invalidation rules?

In another answer which at the time of writing is selected as solution, and which is heavily upvoted and therefore apparently believed, it's asserted that

For a COW string, calling non-const operator[] would require making a copy (and invalidating references), which is disallowed by the [quoted] paragraph above [C++11 §21.4.1/6]. Hence, it's no longer legal to have a COW string in C++11.

That assertion is incorrect and misleading in two main ways:

  • It incorrectly indicates that only the non-const item accessors need to trigger a COW data copying.
    But also the const item accessors need to trigger data copying, because they allow client code to form references or pointers that (in C++11) it's not permitted to invalidate later via the operations that can trigger COW data copying.
  • It incorrectly assumes that COW data copying can cause reference invalidation.
    But in a correct implementation COW data copying, un-sharing the string value, is done at a point before there are any references that can be invalidated.

To see how a correct C++11 COW implementation of basic_string would work, when the O(1) requirements that make this invalid are ignored, think of an implementation where a string can switch between ownership policies. A string instance starts out with policy Sharable. With this policy active there can be no external item references. The instance can transition to Unique policy, and it must do so when an item reference is potentially created such as with a call to .c_str() (at least if that produces a pointer to the internal buffer). In the general case of multiple instances sharing ownership of the value, this entails copying the string data. After that transition to Unique policy the instance can only transition back to Sharable by an operation that invalidates all references, such as assignment.

So, while that answer's conclusion, that COW strings are ruled out, is correct, the reasoning offered is incorrect and strongly misleading.

I suspect the cause of this misunderstanding is a non-normative note in C++11's annex C:

C++11 §C.2.11 [diff.cpp03.strings], about §21.3:

Change: basic_string requirements no longer allow reference-counted strings
Rationale: Invalidation is subtly different with reference-counted strings. This change regularizes behavor (sic) for this International Standard.
Effect on original feature: Valid C ++ 2003 code may execute differently in this International Standard

Here the rationale explains the primary why one decided to remove the C++03 special COW support. This rationale, the why, is not how the standard effectively disallows COW implementation. The standard disallows COW via the O(1) requirements.

In short, the C++11 invalidation rules don't rule out a COW implementation of std::basic_string. But they do rule out a reasonably efficient unrestricted C++03-style COW implementation like the one in at least one of g++'s standard library implementations. The special C++03 COW support allowed practical efficiency, in particular using const item accessors, at the cost of subtle, complex rules for invalidation:

C++03 §21.3/5 which includes “first call” COW support:

References, pointers, and iterators referring to the elements of a basic_string sequence may be invalidated by the following uses of that basic_string object:
— As an argument to non-member functions swap() (, operator>>() (, and getline() (
— As an argument to basic_string::swap().
— Calling data() and c_str() member functions.
— Calling non-const member functions, except operator[](), at(), begin(), rbegin(), end(), and rend().
— Subsequent to any of the above uses except the forms of insert() and erase() which return iterators, the first call to non-const member functions operator[](), at(), begin(), rbegin(), end(), or rend().

These rules are so complex and subtle that I doubt many programmers, if any, could give a precise summary. I could not.

What if O(1) requirements are disregarded?

If the C++11 constant time requirements on e.g. operator[] are disregarded, then COW for basic_string could be technically feasible, but difficult to implement.

Operations which could access the contents of a string without incurring COW data copying include:

  • Concatenation via +.
  • Output via <<.
  • Using a basic_string as argument to standard library functions.

The latter because the standard library is permitted to rely on implementation specific knowledge and constructs.

Additionally an implementation could offer various non-standard functions for accessing string contents without triggering COW data copying.

A main complicating factor is that in C++11 basic_string item access must trigger data copying (un-sharing the string data) but is required to not throw, e.g. C++11 §21.4.5/3 “Throws: Nothing.”. And so it can't use ordinary dynamic allocation to create a new buffer for COW data copying. One way around this is to use a special heap where memory can be reserved without being actually allocated, and then reserve the requisite amount for each logical reference to a string value. Reserving and un-reserving in such a heap can be constant time, O(1), and allocating the amount that one has already reserved, can be noexcept. In order to comply with the standard's requirements, with this approach it seems there would need to be one such special reservation-based heap per distinct allocator.

¹ The const item accessor triggers a COW data copying because it allows the client code to obtain a reference or pointer to the data, which it's not permitted to invalidate by a later data copying triggered by e.g. the non-const item accessor.

  • 3
    "Your example is a good example of an incorrect-for- C++11 implementation. Possibly it was correct for C++03." Yes that's the point of the example. It shows a COW string that was legal in C++03 because it doesn't break the old iterator invalidation rules and is not legal in C++11 because it does break the new iterator invalidation rules. And it also contradicts the statement I quoted in the comment above. Jul 29, 2016 at 8:23
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    What if s isn't shared yet when you call s.c_str()? How do you deal with later invalidation of the pointer returned by c_str()? The string needs to remember if any reference was ever taken, even while it was uniquely owned, and then never allow sharing. That's impractical in the real world. Jul 29, 2016 at 8:38
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    If you'd said sharable not initially shared I would not have argued. Saying something is initially shared is just confusing. Shared with itself? That's not what the word means. But I repeat: your attempt to argue that the C++11 iterator invalidation rules don't forbid some hypothetical COW string that was never used in practice (and would have unacceptable performance), when they most certainly do forbid the kind of COW string that was used in practice, is somewhat academic and pointless. Jul 29, 2016 at 9:29
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    Your proposed COW string is interesting, but I'm not sure how useful it would be. The point of a COW string is to only copy the string data in the event that the two strings are written to. Your suggested implementation requires copying when any user-defined read operation happens. Even if the compiler knows its only a read, it must still copy. Furthermore, copying a Unique string will result in a copy of its string data (presumably to a Sharable state), which again makes COW rather pointless. So without the complexity guarantees, you could write... a really crappy COW string. Jul 29, 2016 at 13:48
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    @JonathanWakely: (1) Your quote is not the question. Here is the question: “Am I correct that C++11 does not admit COW based implementations of std::string? If so, is this restriction explicitly stated somewhere in the new standard (where)?” (2) Your opinion that a COW std::string, when disregarding the O(1) requirements, would be inefficient, is your opinion. I don't know what the performance could be, but I think that that assertion is put forward more for the feel of it, for the vibes that it conveys, than for any relevance to this answer. Aug 3, 2016 at 17:59

From 21.4.2 basic_string constructors and assignment operators [string.cons]

basic_string(const basic_string<charT,traits,Allocator>& str);


2 Effects: Constructs an object of class basic_string as indicated in Table 64. [...]

Table 64 helpfully documents that after construction of an object via this (copy) constructor, this->data() has as value:

points at the first element of an allocated copy of the array whose first element is pointed at by str.data()

There are similar requirements for other similar constructors.


Since it is now guaranteed that strings are stored contiguously and you are now allowed to take a pointer to the internal storage of a string, (i.e. &str[0] works like it would for an array), it's not possible to make a useful COW implementation. You would have to make a copy for way too many things. Even just using operator[] or begin() on a non-const string would require a copy.

  • 1
    I think strings in C++11 are guaranteed to be stored contiguously.
    – mfontanini
    Aug 30, 2012 at 15:03
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    In the past you had to do the copies in all those situations and it was not a problem... Aug 30, 2012 at 15:10
  • @mfontanini yes, but they weren't previously Aug 30, 2012 at 15:56
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    Although C++11 does guarantee strings are contiguous, that is orthogonal to banning COW strings. GCC's COW string is contiguous, so clearly your claim that "it's not possible to make a useful COW implementation" is bogus. Mar 22, 2015 at 18:21
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    @supercat, asking for the backing store (e.g. by calling c_str()) must be O(1) and cannot throw, and must not introduce data races, so it's very difficult to meet those requirements if you lazily concatenate. In practice the only reasonable option is to always store contiguous data. Nov 13, 2015 at 8:29

I was always wondering about immutable cows: once cow is created I could be changed only through assignment from another cow, hence it will be compliant with the standard.

I had time to try it today for a simple comparison test: a map of size N keyed by string/cow with every node holding a set of all strings in the map (we have NxN number of objects).

With strings sized ~300 bytes and N=2000 cows are slightly faster and use almost order of magnitude less memory. See below, sizes are in kbs, run b is with cows.

~/icow$ ./tst 2000
preparation a
done a: time-delta=6 mem-delta=1563276
preparation b
done a: time-delta=3 mem-delta=186384

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