Here are some excerpts from my copy of the 2014 draft standard N4140

22.5 Standard code conversion facets [locale.stdcvt]

3 For each of the three code conversion facets codecvt_utf8, codecvt_utf16, and codecvt_utf8_utf16:
(3.1) — Elem is the wide-character type, such as wchar_t, char16_t, or char32_t.

4 For the facet codecvt_utf8:
(4.1) — The facet shall convert between UTF-8 multibyte sequences and UCS2 or UCS4 (depending on the size of Elem) within the program.

One interpretation of these two paragraphs is that wchar_t must be encoded as either UCS2 or UCS4. I don't like it much because if it's true, we have an important property of the language buried deep in a library description. I have tried to find a more direct statement of this property, but to no avail.

Another interpretation that wchar_t encoding is not required to be either UCS2 or UCS4, and on implementations where it isn't, codecvt_utf8 won't work for wchar_t. I don't like this interpretation much either, because if it's true, and neither char nor wchar_t native encodings are Unicode, there doesn't seem to be a way to portably convert between those native encodings and Unicode.

Which of the two interpretations is true? Is there another one which I overlooked?

Clarification I'm not asking about general opinions about suitability of wchar_t for software development, or properties of wchar_t one can derive from elsewhere. I am interested in these two specific paragraphs of the standard. I'm trying to understand what these specific paragraphs entail or do not entail.

Clarification 2. If 4.1 said "The facet shall convert between UTF-8 multibyte sequences and UCS2 or UCS4 or whatever encoding is imposed on wchar_t by the current global locale" there would be no problem. It doesn't. It says what it says. It appears that if one uses std::codecvt_utf8<wchar_t>, one ends up with a bunch of wchar_t encoded as UCS2 or UCS4, regardless of the current global locale. (There is no way to specify a locale or any character conversion facet for codecvt_utf8). So the question can be rephrased like this: is the conversion result directly usable with the current global locale (and/or with any possible locale) for output, wctype queries and so on? If not, what it is usable for? (If the second interpretation above is correct, the answer would seem to be "nothing").

  • 1
    wchar_t is non-portrable. Eg on Unix it is UTF-32 and on Windows it is UTF-16 (not UCS2) Aug 4, 2016 at 14:55
  • 6
    wchar_t is an integral type. What makes you think it has a fixed encoding? It can store the number 7, and you can interpret that as meaning "the user clicked on the left button". Somewhere else you can interpret 7 in a wchar_T it to mean "activate fire alarm", and elsewhere as a lower case a. The interesting problem is what happens when you read from input and the like, but that isn't the encoding of wchar_t but the encoding the io does... The facets describe what is the encoding result of using that facet on the streaming operation... Aug 4, 2016 at 14:55
  • wchar_t just has to be bigger than char, that's it..
    – David Haim
    Aug 4, 2016 at 14:56
  • 2
    wchar_t is simply capable of containing either UCS2 or UCS4 it is not mandated to.
    – Galik
    Aug 4, 2016 at 14:59
  • An encoding is an assignment from numbers to meaning. A type doesn't come with such semantics.
    – Kerrek SB
    Aug 4, 2016 at 15:00

7 Answers 7


wchar_t is just an integral literal. It has a min value, a max value, etc.

Its size is not fixed by the standard.

If it is large enough, you can store UCS-2 or UCS-4 data in a buffer of wchar_t. This is true regardless of the system you are on, as UCS-2 and UCS-4 and UTF-16 and UTF-32 are just descriptions of integer values arranged in a sequence.

In C++11, there are std APIs that read or write data presuming it has those encodings. In C++03, there are APIs that read or write data using the current locale.

22.5 Standard code conversion facets [locale.stdcvt]

3 For each of the three code conversion facets codecvt_utf8, codecvt_utf16, and codecvt_utf8_utf16:

(3.1) — Elem is the wide-character type, such as wchar_t, char16_t, or char32_t.

4 For the facet codecvt_utf8:

(4.1) — The facet shall convert between UTF-8 multibyte sequences and UCS2 or UCS4 (depending on the size of Elem) within the program.

So here it codecvt_utf8_utf16 deals with utf8 on one side, and UCS2 or UCS4 (depending on how big Elem is) on the other. It does conversion.

The Elem (the wide character) is presumed to be encoded in UCS2 or UCS4 depending on how big it is.

This does not mean that wchar_t is encoded as such, it just means this operation interprets the wchar_t as being encoded as such.

How the UCS2 or UCS4 got into the Elem is not something this part of the standard cares about. Maybe you set it in there with hex constants. Maybe you read it from io. Maybe you calculated it on the fly. Maybe you used a high-quality random-number generator. Maybe you added together the bit-values of an ascii string. Maybe you calculated a fixed-point approximation of the log* of the number of seconds it takes the moon to change the Earth's day by 1 second. Not these paragraphs problems. These pragraphs simply mandate how bits are modified and interpreted.

Similar claims hold in other cases. This does not mandate what format wchar_t have. It simply states how these facets interpret wchar_t or char16_t or char32_t or char8_t (reading or writing).

Other ways of interacting with wchar_t use different methods to mandate how the value of the wchar_t is interpreted.

iswalpha uses the (global) locale to interpret the wchar_t, for example. In some locals, the wchar_t may be UCS2. In others, it might be some insane cthulian encoding whose details enable you to see a new color from out of space.

To be explicit: encodings are not the property of data, or bits. Encodings are properties of interpretation of data. Quite often there is only one proper or reasonable interpretation of data that makes any sense, but the data itself is bits.

The C++ standard does not mandate what is stored in a wchar_t. It does mandate what certain operations interpret the contents of a wchar_t to be. That section describes how some facets interpret the data in a wchar_t.



wchar is only required to hold the biggest locale supported by the compiler. Which could theoretically fit in a char.

Type wchar_t is a distinct type whose values can represent distinct codes for all members of the largest extended character set specified among the supported locales (22.3.1).

— C++ [basic.fundamental] 3.9.1/5

as such it's not even required to support Unicode

The width of wchar_t is compiler-specific and can be as small as 8 bits. Consequently, programs that need to be portable across any C or C++ compiler should not use wchar_t for storing Unicode text. The wchar_t type is intended for storing compiler-defined wide characters, which may be Unicode characters in some compilers.

ISO/IEC 10646:2003 Unicode standard 4.0


Let us differentiate between wchar_t and string literals built using the L prefix.

wchar_t is just an integer type, which may be larger than char.

String literals using the L prefix will generate strings using wchar_t characters. Exactly what that means is implementation-dependent. There is no requirement that such literals use any particular encoding. They might use UTF-16, UTF-32, or something else that has nothing to do with Unicode at all.

So if you want a string literal which is guaranteed to be encoded in a Unicode format, across all platforms, use u8, u, or U prefixes for the string literal.

One interpretation of these two paragraphs is that wchar_t must be encoded as either UCS2 or UCS4.

No, that is not a valid interpretation. wchar_t has no encoding; it's just a type. It is data which is encoded. A string literal prefixed by L may or may not be encoded in UCS2 or UCS4.

If you provide codecvt_utf8 a string of wchar_ts which are encoded in UCS2 or UCS4 (as appropriate to sizeof(wchar_t)), then it will work. But not because of wchar_t; it only works because the data you provide it is correctly encoded.

If 4.1 said "The facet shall convert between UTF-8 multibyte sequences and UCS2 or UCS4 or whatever encoding is imposed on wchar_t by the current global locale" there would be no problem.

The whole point of those codecvt_* facets is to perform locale-independent conversions. If you want locale-dependent conversions, you shouldn't use them. You should instead use the global codecvt facet.

  • 2
    @n.m.: My interpretation of those paragraphs is that they mean exactly what they say. Your interpretation of them is confused because your understanding of the words they use is confused. That's why I explained what those words mean. wchar_t is not an encoding. It has no encoding; it's just a type. Aug 4, 2016 at 15:36
  • There is one or more encodings imposed on wchar_t by various locale facets. I'm asking whether any or all of them must be UCS-whatever. Aug 4, 2016 at 15:49
  • 1
    @n.m.: No, locale facets impose nothing on wchar_t. They impose encodings on certain operations. So you could build a string for an encoding with a iostream by using a locale that imposes that encoding on the stream. But that has nothing to do with the behavior of wchar_t itself; that only affects the data stored in the wchar_t array. And locales impose nothing on codecvt facets. Aug 4, 2016 at 15:50
  • "They impose encodings on certain operations" That's imposing an encoding on wchar_t in my book. I'm building strings to perform operations on them, not to frame them and hang them on the wall. codecvt is a locale facet, locales just have them. Aug 4, 2016 at 16:02
  • I want a very simple thing, to be able to convert UTF-8 to wchar_t in a way that is consistent with other uses of wchar_t. Namely, printing to (untampered with) wcout, comparing with L"" literals, and/or querying isw... bits, without touching my current global locale or stream locales. I know I can convert UTF-8 to UCS4 and stuff these values to wchar_t, but this seems to be a rather useless exercise, unless I happen to know that operations I mentioned do in fact use UCS4. Aug 4, 2016 at 16:36

As Elem can be wchar_t, char16_t, or char32_t, the clause 4.1 says nothing about a required wchar_t encoding. It states something about the conversion performed.

From the wording, it is clear that the conversion is between UTF-8 and either UCS-2 or UCS-4, depending on the size of Elem. So if wchar_t is 16 bits, the conversion will be with UCS-2, and if it is 32 bits, UCS-4.

Why does the standard mention UCS-2 and UCS-4 and not UTF-16 and UTF-32 ? Because codecvt_utf8 will convert a multi-byte UTF8 to a single wide character:

  • UCS-2 is a subset of unicode, but there is no surogate pair encoding contrary to UTF-16
  • UCS-4 is the same as UTF-32, now (but looking at the growing number of emojis, maybe one day there couldn't be enough of 32 bits, and you would have a UTF-64, and UTF32 surrogate pairs that would not be supported by codecvt_utf8)

Although, it is not clear to me what will happen, if an UTF-8 text would contain a sequence corresponds to a unicode character that is not available in UCS-2 used for a receiving char16_t.

  • Re your last statement: the conversion will simply fail IMO. Aug 4, 2016 at 16:44

Both your interpretations are incorrect. The standard doesn't require that there be a single wchar_t encoding, just like it doesn't require a single char encoding. The codecvt_utf8 facet must convert between UTF-8 and UCS-2 or UCS-4. This true even UTF-8, UCS-2, and UCS-4 are not supported as character sets in any locale.

If Elem is of type wchar_t and isn't big enough to store a UCS-2 value than then the conversion operations of the codecvt_utf8 facet are undefined because the standard doesn't say what happens in that case. If it is big enough (or if you want to argue that the standard requires that it must be big enough) then it's merely implementation defined whether the UCS-2 or UCS-4 wchar_t values the facet generates or consumes are in an encoding compatible with any locale defined wchar_t encoding.

  • I don't see how they can be both incorrect. It seems to me that your answer implies that the second one is correct (if not, please point out where it fails). Aug 4, 2016 at 16:47
  • @n.m Your second interpretation fails on two points. First it assumes there is one single global wchar_t encoding at time. There's a single default locale-specific wide character encoding, but this only affects certain local dependent library functions. Second the codecvt_utf8 facet is required to convert between UCS-2/4 and UTF-8 values when Elem is wchar_t, if wchar_t is big enough. If wchar_t is, say, 16-bits, then then the convert_utf8/16 facets must convert between UCS-2, but this doesn't place a requirement on anything else to use UCS-2.
    – Ross Ridge
    Aug 4, 2016 at 17:46
  • Frankly I don't see where the second interpretation assumes anything like that. If in some implementation the default wchar_t encoding of any locale, or some defined locale, is UCS4, then obviously codecvt_utf8<wchar_t> is going to be compatible with that locale encoding. The question is whether an implementation is required to make it true or not, The 2nd interpretation says no, it is not. But perhapss it is not worded the best possible way. Aug 4, 2016 at 18:23
  • @n.m. Your second interpretation says that codecvt_utf8 won't work if "wchar_t encoding is not required to be either UCS2 or UCS4". The standard doesn't require "wchar_t encoding", whatever you think that means, to be UCS-2/4, but it does require that codecvt_ut8 to work. You could argue that the requirements on codecvt_utf8 place requirements on the size of wchar_t, but they don't place requirements on the encoding used by anything else, anywhere else in the standard.
    – Ross Ridge
    Aug 4, 2016 at 18:50
  • "it does require that codecvt_ut8 to work" perhaps, for some definition of "work". It doesn't require it to work sensibly (i.e. in a way that is compatible with other wchar_t functionality; if I convert u"abc", the result is not required to be equal to L"abc"` which falls under "not working" in my book). I have added my own answer, you are welcome to comment. Aug 4, 2016 at 19:48

It appears your first conclusion is shared by Microsoft who enumerate the possible options, and note that UTF-16, although "widely used as such[sic]" is not a valid encoding.

The same wording is also used by QNX, which points at the source of the wording: Both QNX and Microsoft derive their Standard Library implementation from Dinkumware.

Now, as it happens, Dinkumware is also the author of N2401 which introduced these classes. So I'm going to side with them.

  • It appears your first conclusion is shared by Microsoft - Could you elaborate? The only thing I can get from that link is the definition of UCS-* / UTF-*, not that wchar_t must be encoded as UCS-2/4.
    – Holt
    Aug 4, 2016 at 15:43
  • Hmm, Microsoft says "Represents a locale facet that converts between wide characters encoded as UCS-2 or UCS-4 ...". It doesn't seem to imply there are no other possibilities. I remember working with machines where wchar_t was JIS one or the other, are such environments unsupported by current C++? Aug 4, 2016 at 15:43
  • @Holt: That bit follows "... several character encodings. For wide characters ... : " followed by the list defining UCS2, UCS4, and UTF-16. There is no hint to suggest the list is merely examples; it appears to be exhaustive.
    – MSalters
    Aug 4, 2016 at 15:48
  • @MSalters These are the only ones that appears in the standard, so they merely define possible interpretation of term in the standard. At least that is how I see it.
    – Holt
    Aug 4, 2016 at 15:52

The first interpretation is conditionally true.

If __STDC_ISO_10646__ macro (imported from C) is defined, then wchar_t is a superset of some version of Unicode.

An integer literal of the form yyyymmL (for example, 199712L). If this symbol is defined, then every character in the Unicode required set, when stored in an object of type wchar_t, has the same value as the short identifier of that character. The Unicode required set consists of all the characters that are defined by ISO/IEC 10646, along with all amendments and technical corrigenda as of the specified year and month.

It appears that if the macro is defined, some kind of UCS4 can be assumed. (Not UCS2 as ISO 10646 never had a 16-bit version; the first release of ISO 10646 corresponds to Unicode 2.0).

So if the macro is defined, then

  • there is a "native" wchar_t encoding
  • it is a superset of some version of UCS4
  • the conversion provided by codecvt_utf8<wchar_t> is compatible with this native encoding

None of these things are required to hold if the macro is not defined.

There are also __STDC_UTF_16__ and __STDC_UTF_32__ but the C++ standard doesn't say what they mean. The C standard says that they signify UTF-16 and UTF-32 encodings for char16_t and char32_t respectively, but in C++ these encodings are always used.

Incidentally, the functions mbrtoc32 and c32rtomb convert back and forth between char sequences and char32_t sequences. In C they only use UTF-32 if __STDC_UTF_32__ is defined, but in C++ UTF-32 is always used for char32_t. So it would appear than even if __STDC_ISO_10646__ is not defined, it should be possible to convert between UTF-8 and wchar_t by going from UTF-8 to UTF-32-encoded char32_t to natively encoded char to natively encoded wchar_t, but I'm afraid of this complex stuff.

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