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I know that in C++03, technically the std::basic_string template is not required to have contiguous memory. However, I'm curious how many implementations exist for modern compilers that actually take advantage of this freedom. For example, if one wants to use basic_string to receive the results of some C API (like the example below), it seems silly to allocate a vector just to turn it into a string immediately.


DWORD valueLength = 0;
DWORD type;
LONG errorCheck = RegQueryValueExW(

if (errorCheck != ERROR_SUCCESS)
else if (valueLength == 0)
    return std::wstring();

std::wstring buffer;
    errorCheck = RegQueryValueExW(
} while (errorCheck == ERROR_MORE_DATA);

if (errorCheck != ERROR_SUCCESS)

return buffer;

I know code like this might slightly reduce portability because it implies that std::wstring is contiguous -- but I'm wondering just how unportable that makes this code. Put another way, how may compilers actually take advantage of the freedom having noncontiguous memory allows?

EDIT: I updated this question to mention C++03. Readers should note that when targeting C++11, the standard now requires that basic_string be contiguous, so the above question is a non issue when targeting that standard.

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Unless you're certain that MSVC is successfully giving you the RVO (even though you have two different returns, one a temporary and one a variable name), then you're not "allowed" to worry about an extra copy ;-) –  Steve Jessop Feb 13 '10 at 2:08
I don't believe RVO would optimize a copy between vector and string.... –  Billy ONeal Feb 13 '10 at 2:14
What I mean is that if the current code has no RVO then it's "create string. Copy it to the return value". You're talking maybe 50% more copying if you change that to "create vector. Copy it to string. Copy it to return value". Or maybe no extra copying at all if you do return std::wstring(vec.begin(), vec.end()); and get "create vector. Copy it to return value (via RVO)". I'd worry about whether I could detect the speed difference before I worried about how portable the resulting code was. But that's just this example, which is why it's a comment not an answer. –  Steve Jessop Feb 13 '10 at 2:31
If you rely on undefined behavior, please comment it. That way the bug it causes when you port the code, or when the underlying implementation changes, can be found later. Even if the chance of that approaches zero, do it anyway. Better to spend five slightly annoying seconds now than multiple painful hours later. Also, this sounds like pre-mature optimization at the cost of correctness. –  Merlyn Morgan-Graham Feb 13 '10 at 3:01
Premature is optimising before you have established that (a) the existing program is too slow, and (b) this bit of code is responsible for a significant part of the time. Since you've proved that it speeds up your app it's not premature, and IMO you're right to investigate whether it's safe. If you had done it on the basis that it speeds up this one function, not measuring whether that function is responsible for 90% of your runtime or 0.001%, then it would be premature. I'd naively guess that finding values in the registry is way slower than copying them, but apparently not. –  Steve Jessop Feb 13 '10 at 12:35

5 Answers 5

up vote 20 down vote accepted

I'd consider it quite safe to assume that std::string allocates its storage contiguously.

At the present time, all known implementations of std::string allocate space contiguously.

Moreover, the current draft of C++ 0x (N3000) [Edit: Warning, direct link to large PDF] requires that the space be allocated contiguously (§21.4.1/5):

The char-like objects in a basic_string object shall be stored contiguously. That is, for any basic_string object s, the identity &*(s.begin() + n) == &*s.begin() + n shall hold for all values of n such that 0 <= n < s.size().

As such, the chances of a current or future implementation of std::string using non-contiguous storage are essentially nil.

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"all known implementations". In particular, all that matters for a WinAPI call is the various versions of Windows. So "all known implementations" might actually be "all implementations". –  Steve Jessop Feb 13 '10 at 2:15
@Steve Jessop: Not really, std::basic_string is a compiler feature, not a Windows feature. What version of windows the compiled code runs on really doesn't matter here. –  Billy ONeal Feb 13 '10 at 2:18
Fair point. You could perhaps say, though, "this code is only supported on Microsoft compilers". Still not strictly the same as Windows versions, but the point is that you only have to worry about a fixed set of implementations. Future MS compilers will support most or all of C++0x. –  Steve Jessop Feb 13 '10 at 2:30
@Steve:In this case, the "all known implementations" was (at least if I recall correctly) "all implementations known to anybody on the committee." Given that virtually every C++ implementer is represented, it probably does mean all (publicly available) implementations. If you want to get technical, I modified SGI's rope class to conform (or at least get really close) years ago, but I'm pretty no eyes but mine have ever looked at that, so it hardly counts (and I haven't used it or even looked at it in years, so I certainly don't care). –  Jerry Coffin Feb 13 '10 at 3:15
@Steve:Keep in mind, however, the requirement's been there since at least N2284 (05/07/2007), so by now there's been plenty of time for anybody who wasn't there to speak up, but nobody has. Admittedly isn't a proof that it hasn't been done, but does seem like pretty decent evidence that if anybody's using the current leeway, they still think contiguous allocation offers more benefit. –  Jerry Coffin Feb 13 '10 at 4:47

A while back there was a question about being able to write to the storage for a std::string as if it were an array of characters, and it hinged on whether the contents of a std::string were contiguous:

My answer indicated that according to a couple well regarded sources (Herb Sutter and Matt Austern) the current C++ standard does require std::string to store its data contiguous under certain conditions (once you call str[0] assuming str is a std::string) and that that fact pretty much forces the hand of any implementation.

Basically, if you combine the promises made by string::data() and string::operator[]() you conclude that &str[0] needs to return a contiguous buffer. Therefore Austern suggests that the committee just make that explicit, and apparently that's what'll happen in the 0x standard (or are they calling it the 1x standard now?).

So strictly speaking an implementation doesn't have to implement std::string using contiguous storage, but it has to do so pretty much on demand. And your example code does just that by passing in &buffer[0].


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The result is undefined and I would not do it. The cost of reading into a vector and then converting to a string is trivial in modern c++ heaps. VS the risk that your code will die in windows 9

also, doesnt that need a const_cast on &buffer[0]?

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String implementations have nothing to do with the windows API and therefore should have nothing to do with what version of windows someone uses. Yes, it's undefined behavior according to the standard. But it's okay for every compiler of which I am aware. I'm curious how many compilers actually take advantage of the latitude the standard gives them. –  Billy ONeal Feb 13 '10 at 2:06
tyically new versions of windows ship with new version of c runtime. the point is that undefined means that it can change mysteriously in the future, why take the risk? Practically, I have never seem a string impl that doesnt lay the string out as a nice classic array. But I still wouldnt do it –  pm100 Feb 13 '10 at 2:09
Undefined does NOT mean that it can change mysteriously in the future. Undefined means compilers can implement it however they want. Once the code is compiled, it's behavior cannot change, unless it's calling dynamic libraries. Since string does not call DLLs, future versions of windows will not break it. (Unless I use a dynamic C runtime -- then I suppose it's possible but still unlikely) I'm not asking if it's a good idea to do this -- I'm asking if there are any compilers that care. –  Billy ONeal Feb 13 '10 at 2:13
also, doesnt that need a const_cast on &buffer[0]? <-- No. std::basic_string<t>::operator[] returns a non-const reference to the first element in the string. cplusplus.com/reference/string/string/operator[] –  Billy ONeal Feb 13 '10 at 2:20
are we having fun yet? :-) All compilers that I have seen do it the way we both expect. OK? But i still wouldnt do it –  pm100 Feb 13 '10 at 2:27

Edit: You want to call &buffer[0], not buffer.data(), because [] returns a non-const reference and does notify the object that its contents can change unexpectedly.

It would be cleaner to do buffer.data(), but you should worry less about contiguous memory than memory shared between structures. string implementations can and do expect to be told when an object is being modified. string::data specifically requires that the program not modify the internal buffer returned.

VERY high chances that some implementation will create one buffer for all strings uninitialized besides having length set to 10 or whatever.

Use a vector or even an array with new[]/delete[]. If you really can't copy the buffer, legally initialize the string to something unique before changing it.

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That's why I'm calling std::basic_string<t>::resize first. Calling resize essentially forces a reallocation of the underlying buffer that the string object is using. See Scott Myers Effective STL Item #16: "Know how to pass Vector and String data to legacy APIs." –  Billy ONeal Feb 13 '10 at 19:42
@Billy: I saw what you're doing. "Essentially forces" is not "guarantees." From the implementation's perspective, you have a number of objects which should contain all zeroes, and it was never given a chance to see whether they do or don't because you never called a non-const member function after resize. –  Potatoswatter Feb 13 '10 at 22:17
Umm.. resize itself is a non-const member function. Calling resize forces the implementation to allocate and default construct the values in the string -- resize modifies the string itself. Therefore, even in a reference counted implementation, the string must be created from scratch, because the content of the string has changed. I believe you are confusing resize with reserve here. Reserve changes the underlying allocation but not the data, so it's possible that an implementation might share. But resize changes both, ergo no sharing. –  Billy ONeal Feb 14 '10 at 0:49
See example here: cplusplus.com/reference/string/string/resize Note that the string content, not just the underlying representation, is changed with the call to resize. –  Billy ONeal Feb 14 '10 at 0:59
@Billy: For a type like char, there is no pretense of calling a constructor. The implementation can keep a zeroed-out scratch space to store all small strings resize'd from empty. (Not to say it's a great idea.) But otherwise I was completely wrong, answer reversed. (But, calling both data and [] would unambiguously satisfy both requirements of a modifiable contiguous buffer.) –  Potatoswatter Feb 14 '10 at 2:04

Of course, allocating a vector here is silly. Using std::wstring here is not wise also. It's better to use a char array to call the winapi. construct a wstring when returning value.

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I made this up as an example -- assuming I'm reading a unicode string value from the registry. Use any Win32 function you like and the question is the same. –  Billy ONeal Feb 13 '10 at 2:11

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