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This intrigues me, so I'm going to ask - for what reason is wchar_t not used so widely on Linux/Linux-like systems as it is on Windows? Specifically, the Windows API uses wchar_t internally whereas I believe Linux does not and this is reflected in a number of open source packages using char types.

My understanding is that given a character c which requires multiple bytes to represent it, then in a char[] form c is split over several parts of char* whereas it forms a single unit in wchar_t[]. Is it not easier, then, to use wchar_t always? Have I missed a technical reason that negates this difference? Or is it just an adoption problem?

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up vote 11 down vote accepted

wchar_t is a wide character with platform-defined width, which doesn't really help much.

UTF-8 characters span 1-4 bytes per character. UCS-2, which spans exactly 2 bytes per character, is now obsolete and can't represent the full Unicode character set.

Linux applications that support Unicode tend to do so properly, above the byte-wise storage layer. Windows applications tend to make this silly assumption that only two bytes will do.

wchar_t's Wikipedia article briefly touches on this.

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Windows uses UTF-16 which does not make the assumption that two bytes are enough. UTF-16 can represent the entirety of Unicode. UTF-16's Wikipedia article briefly touches on this :-) – Joey Jan 3 '11 at 21:06
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On the other hand, lots of Linux apps make the "silly assumption" that UTF-8 means they don't have to change anything to make their code operate correctly w.r.t. the unicode standard, and can still use plain char *s everywhere and not pay attention to things. – Billy ONeal Jan 3 '11 at 21:07
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@Joey: Yes, and that's exactly why windows UTF-16 is no better than UTF-8 in the end : you can't predict character size. Henceforth you can't move by a given number of char inside strings. So what's the point of using two times the space when writing english messages ? – kriss Jan 3 '11 at 21:12
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@kriss @Tomalak @Joey: Do keep in mind that when "Unicode" was added to Win32, 2 bytes was enough to encode any code point. (NT3.51 shipped well before 1996, when UTF-16 was introduced) This is why Windows uses UTF-16 now -- they had already decided to use wchar_t, and they couldn't break the entire API. Also, even if your app is using UCS-2 only, you still can encode most any language in modern use without difficulty. – Billy ONeal Jan 3 '11 at 21:20
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Ignorance is often confused with racism. I'll let you figure this one out by yourself. – Hans Passant Jan 4 '11 at 0:38

The first people to use UTF-8 on a Unix-based platform explained:

The Unicode Standard [then at version 1.1] defines an adequate character set but an unreasonable representation [UCS-2]. It states that all characters are 16 bits wide [no longer true] and are communicated and stored in 16-bit units. It also reserves a pair of characters (hexadecimal FFFE and FEFF) to detect byte order in transmitted text, requiring state in the byte stream. (The Unicode Consortium was thinking of files, not pipes.) To adopt this encoding, we would have had to convert all text going into and out of Plan 9 between ASCII and Unicode, which cannot be done. Within a single program, in command of all its input and output, it is possible to define characters as 16-bit quantities; in the context of a networked system with hundreds of applications on diverse machines by different manufacturers [italics mine], it is impossible.

The italicized part is less relevant to Windows systems, which have a preference towards monolithic applications (Microsoft Office), non-diverse machines (everything's an x86 and thus little-endian), and a single OS vendor.

And the Unix philosophy of having small, single-purpose programs means fewer of them need to do serious character manipulation.

The source for our tools and applications had already been converted to work with Latin-1, so it was ‘8-bit safe’, but the conversion to the Unicode Standard and UTF[-8] is more involved. Some programs needed no change at all: cat, for instance, interprets its argument strings, delivered in UTF[-8], as file names that it passes uninterpreted to the open system call, and then just copies bytes from its input to its output; it never makes decisions based on the values of the bytes...Most programs, however, needed modest change.

...Few tools actually need to operate on runes [Unicode code points] internally; more typically they need only to look for the final slash in a file name and similar trivial tasks. Of the 170 C source programs...only 23 now contain the word Rune.

The programs that do store runes internally are mostly those whose raison d’être is character manipulation: sam (the text editor), sed, sort, tr, troff, (the window system and terminal emulator), and so on. To decide whether to compute using runes or UTF-encoded byte strings requires balancing the cost of converting the data when read and written against the cost of converting relevant text on demand. For programs such as editors that run a long time with a relatively constant dataset, runes are the better choice...

UTF-32, with code points directly accessible, is indeed more convenient if you need character properties like categories and case mappings.

But widechars are awkward to use on Linux for the same reason that UTF-8 is awkward to use on Windows. GNU libc has no _wfopen or _wstat function.

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UTF-8, being compatible to ASCII, makes it possible to ignore Unicode somewhat.

Often, programs don't care (and in fact, don't need to care) about what the input is, as long as there is not a \0 that could terminate strings. See:

char buf[whatever];
printf("Your favorite pizza topping is which?\n");
fgets(buf, sizeof(buf), stdin); /* Jalapeños */
printf("%s it shall be.\n", buf);

The only times when I found I needed Unicode support is when I had to have a multibyte character as a single unit (wchar_t); e.g. when having to count the number of characters in a string, rather than bytes. iconv from utf-8 to wchar_t will quickly do that. For bigger issues like zero-width spaces and combining diacritics, something more heavy like icu is needed—but how often do you do that anyway?

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More common is case-insensitive comparison. But Linux doesn't need it for filenames. – dan04 Jan 4 '11 at 1:41

wchar_t is not the same size on all platforms. On Windows it is a UTF-16 code unit that uses two bytes. On other platforms it typically uses 4 bytes (for UCS-4/UTF-32). It is therefore unlikely that these platforms would standardize on using wchar_t, since it would waste a lot of space.

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Well, it could also be a UTF-16 surrogate pair. – Billy ONeal Jan 3 '11 at 21:05
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Storing surrogates in wchar_t is not only non-conformant, but makes it impossible to implement a UTF-8 multibyte encoding or any multibyte encoding that supports non-BMP characters with the standard library mbrtowc function. See stackoverflow.com/questions/3228828/… – R.. Jan 4 '11 at 4:03
    
@R.: I don't see how it could be "non-conformant". What are you stipulating it should conform to? The wctombr and mbrtowc functions don't define the encodings on which they operate anyway so one cannot rely on their particular behavior in that respect. – Billy ONeal Jan 4 '11 at 18:17
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Why is UTF-16 unacceptable for wchar_t? It works fine, as long as you interpret "character" to mean codeunit and not codepoint. A UTF-16 encoded string, even one that uses surrogates, can be represented with wchar_t, as long as each codeunit has its own wchar_t element within the string. – Remy Lebeau Jan 6 '11 at 2:13
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@Remy: Because the mbrtowc function cannot behave as specified when a single multibyte character must translate to two or more wchar_t values. See the question I linked. – R.. May 25 '11 at 23:27

The main libc library on Linux, glibc only got full Unicode support (mostly bug-free version not the first version) in its 2.3.3 release and that was in 2004.

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And even then, of course C runtime functions like strstr do not work correctly w.r.t. unicode -- you have to use glibc specific extensions to get unicode correct functionality. – Billy ONeal Jan 3 '11 at 21:08
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@Billy: huh? strstr is to search for exact substrings, not canonically equivalent substrings, which is a very different semantic. The former is useful all over the place. The latter is rarely useful except in an interactive "search for text" operation in a document, where you'd already have to do much higher-level text handling than any language can provide internally. – R.. Jan 4 '11 at 4:01
    
@R. Oops - I meant strchr. Sorry, it's been a long day. – Billy ONeal Jan 4 '11 at 4:07
    
strstr works fine searching for multibyte characters, though. :-) – R.. May 25 '11 at 23:28

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