X-Git-Url: https://git.saurik.com/wxWidgets.git/blobdiff_plain/880efa2a137ce3e3f39236d0dc85f5d2dacdda12..c8c77ee2af68bcea8ba157b4d5a4e2cd5b4912bd:/docs/doxygen/overviews/unicode.h diff --git a/docs/doxygen/overviews/unicode.h b/docs/doxygen/overviews/unicode.h index 6573680581..4013ff8e06 100644 --- a/docs/doxygen/overviews/unicode.h +++ b/docs/doxygen/overviews/unicode.h @@ -3,205 +3,396 @@ // Purpose: topic overview // Author: wxWidgets team // RCS-ID: $Id$ -// Licence: wxWindows license +// Licence: wxWindows licence ///////////////////////////////////////////////////////////////////////////// /** @page overview_unicode Unicode Support in wxWidgets -This section briefly describes the state of the Unicode support in wxWidgets. -Read it if you want to know more about how to write programs able to work with -characters from languages other than English. +This section describes how does wxWidgets support Unicode and how can it affect +your programs. +Notice that Unicode support has changed radically in wxWidgets 3.0 and a lot of +existing material pertaining to the previous versions of the library is not +correct any more. Please see @ref overview_changes_unicode for the details of +these changes. + +You can skip the first two sections if you're already familiar with Unicode and +wish to jump directly in the details of its support in the library: @li @ref overview_unicode_what -@li @ref overview_unicode_ansi +@li @ref overview_unicode_encodings @li @ref overview_unicode_supportin +@li @ref overview_unicode_pitfalls @li @ref overview_unicode_supportout @li @ref overview_unicode_settings -@li @ref overview_unicode_traps -
@section overview_unicode_what What is Unicode? -wxWidgets has support for compiling in Unicode mode on the platforms which -support it. Unicode is a standard for character encoding which addresses the -shortcomings of the previous, 8 bit standards, by using at least 16 (and -possibly 32) bits for encoding each character. This allows to have at least -65536 characters (what is called the BMP, or basic multilingual plane) and -possible 2^32 of them instead of the usual 256 and is sufficient to encode all -of the world languages at once. More details about Unicode may be found at -. - -As this solution is obviously preferable to the previous ones (think of -incompatible encodings for the same language, locale chaos and so on), many -modern operating systems support it. The probably first example is Windows NT -which uses only Unicode internally since its very first version. - -Writing internationalized programs is much easier with Unicode and, as the -support for it improves, it should become more and more so. Moreover, in the -Windows NT/2000 case, even the program which uses only standard ASCII can -profit from using Unicode because they will work more efficiently - there will -be no need for the system to convert all strings the program uses to/from -Unicode each time a system call is made. - - -@section overview_unicode_ansi Unicode and ANSI Modes - -As not all platforms supported by wxWidgets support Unicode (fully) yet, in -many cases it is unwise to write a program which can only work in Unicode -environment. A better solution is to write programs in such way that they may -be compiled either in ANSI (traditional) mode or in the Unicode one. - -This can be achieved quite simply by using the means provided by wxWidgets. -Basically, there are only a few things to watch out for: - -- Character type (@c char or @c wchar_t) -- Literal strings (i.e. @c "Hello, world!" or @c '*') -- String functions (@c strlen(), @c strcpy(), ...) -- Special preprocessor tokens (@c __FILE__, @c __DATE__ and @c __TIME__) - -Let's look at them in order. First of all, each character in an Unicode program -takes 2 bytes instead of usual one, so another type should be used to store the -characters (@c char only holds 1 byte usually). This type is called @c wchar_t -which stands for @e wide-character type. - -Also, the string and character constants should be encoded using wide -characters (@c wchar_t type) which typically take 2 or 4 bytes instead of -@c char which only takes one. This is achieved by using the standard C (and -C++) way: just put the letter @c 'L' after any string constant and it becomes a -@e long constant, i.e. a wide character one. To make things a bit more -readable, you are also allowed to prefix the constant with @c 'L' instead of -putting it after it. - -Of course, the usual standard C functions don't work with @c wchar_t strings, -so another set of functions exists which do the same thing but accept -@c wchar_t* instead of @c char*. For example, a function to get the length of a -wide-character string is called @c wcslen() (compare with @c strlen() - you see -that the only difference is that the "str" prefix standing for "string" has -been replaced with "wcs" standing for "wide-character string"). - -And finally, the standard preprocessor tokens enumerated above expand to ANSI -strings but it is more likely that Unicode strings are wanted in the Unicode -build. wxWidgets provides the macros @c __TFILE__, @c __TDATE__ and -@c __TTIME__ which behave exactly as the standard ones except that they produce -ANSI strings in ANSI build and Unicode ones in the Unicode build. - -To summarize, here is a brief example of how a program which can be compiled -in both ANSI and Unicode modes could look like: - -@code -#ifdef __UNICODE__ - wchar_t wch = L'*'; - const wchar_t *ws = L"Hello, world!"; - int len = wcslen(ws); - - wprintf(L"Compiled at %s\n", __TDATE__); -#else // ANSI - char ch = '*'; - const char *s = "Hello, world!"; - int len = strlen(s); - - printf("Compiled at %s\n", __DATE__); -#endif // Unicode/ANSI -@endcode - -Of course, it would be nearly impossibly to write such programs if it had to -be done this way (try to imagine the number of UNICODE checkes an average -program would have had!). Luckily, there is another way - see the next section. +Unicode is a standard for character encoding which addresses the shortcomings +of the previous standards (e.g. the ASCII standard), by using 8, 16 or 32 bits +for encoding each character. +This allows enough code points (see below for the definition) sufficient to +encode all of the world languages at once. +More details about Unicode may be found at http://www.unicode.org/. + +From a practical point of view, using Unicode is almost a requirement when +writing applications for international audience. Moreover, any application +reading files which it didn't produce or receiving data from the network from +other services should be ready to deal with Unicode. + + +@section overview_unicode_encodings Unicode Representations and Terminology + +When working with Unicode, it's important to define the meaning of some terms. + +A glyph is a particular image (usually part of a font) that +represents a character or part of a character. +Any character may have one or more glyph associated; e.g. some of the possible +glyphs for the capital letter 'A' are: + +@image html overview_unicode_glyphs.png + +Unicode assigns each character of almost any existing alphabet/script a number, +which is called code point; it's typically indicated in documentation +manuals and in the Unicode website as @c U+xxxx where @c xxxx is an hexadecimal number. + +Note that typically one character is assigned exactly one code point, but there +are exceptions; the so-called precomposed characters +(see http://en.wikipedia.org/wiki/Precomposed_character) or the ligatures. +In these cases a single "character" may be mapped to more than one code point or +viceversa more characters may be mapped to a single code point. + +The Unicode standard divides the space of all possible code points in planes; +a plane is a range of 65,536 (1000016) contiguous Unicode code points. +Planes are numbered from 0 to 16, where the first one is the @e BMP, or Basic +Multilingual Plane. +The BMP contains characters for all modern languages, and a large number of +special characters. The other planes in fact contain mainly historic scripts, +special-purpose characters or are unused. + +Code points are represented in computer memory as a sequence of one or more +code units, where a code unit is a unit of memory: 8, 16, or 32 bits. +More precisely, a code unit is the minimal bit combination that can represent a +unit of encoded text for processing or interchange. + +The UTF or Unicode Transformation Formats are algorithms mapping the Unicode +code points to code unit sequences. The simplest of them is UTF-32 where +each code unit is composed by 32 bits (4 bytes) and each code point is always +represented by a single code unit (fixed length encoding). +(Note that even UTF-32 is still not completely trivial as the mapping is different +for little and big-endian architectures). UTF-32 is commonly used under Unix systems for +internal representation of Unicode strings. + +Another very widespread standard is UTF-16 which is used by Microsoft Windows: +it encodes the first (approximately) 64 thousands of Unicode code points +(the BMP plane) using 16-bit code units (2 bytes) and uses a pair of 16-bit code +units to encode the characters beyond this. These pairs are called @e surrogate. +Thus UTF16 uses a variable number of code units to encode each code point. + +Finally, the most widespread encoding used for the external Unicode storage +(e.g. files and network protocols) is UTF-8 which is byte-oriented and so +avoids the endianness ambiguities of UTF-16 and UTF-32. +UTF-8 uses code units of 8 bits (1 byte); code points beyond the usual english +alphabet are represented using a variable number of bytes, which makes it less +efficient than UTF-32 for internal representation. + +As visual aid to understand the differences between the various concepts described +so far, look at the different UTF representations of the same code point: + +@image html overview_unicode_codes.png + +In this particular case UTF8 requires more space than UTF16 (3 bytes instead of 2). + +Note that from the C/C++ programmer perspective the situation is further complicated +by the fact that the standard type @c wchar_t which is usually used to represent the +Unicode ("wide") strings in C/C++ doesn't have the same size on all platforms. +It is 4 bytes under Unix systems, corresponding to the tradition of using +UTF-32, but only 2 bytes under Windows which is required by compatibility with +the OS which uses UTF-16. + +Typically when UTF8 is used, code units are stored into @c char types, since +@c char are 8bit wide on almost all systems; when using UTF16 typically code +units are stored into @c wchar_t types since @c wchar_t is at least 16bits on +all systems. This is also the approach used by wxString. +See @ref overview_string for more info. + +See also http://unicode.org/glossary/ for the official definitions of the +terms reported above. @section overview_unicode_supportin Unicode Support in wxWidgets -In wxWidgets, the code fragment from above should be written instead: - +Since wxWidgets 3.0 Unicode support is always enabled and building the library +without it is not recommended any longer and will cease to be supported in the +near future. This means that internally only Unicode strings are used and that, +under Microsoft Windows, Unicode system API is used which means that wxWidgets +programs require the Microsoft Layer for Unicode to run on Windows 95/98/ME. + +However, unlike the Unicode build mode of the previous versions of wxWidgets, this +support is mostly transparent: you can still continue to work with the @b narrow +(i.e. current locale-encoded @c char*) strings even if @b wide +(i.e. UTF16-encoded @c wchar_t* or UTF8-encoded @c char*) strings are also +supported. Any wxWidgets function accepts arguments of either type as both +kinds of strings are implicitly converted to wxString, so both @code -wxChar ch = wxT('*'); -wxString s = wxT("Hello, world!"); -int len = s.Len(); +wxMessageBox("Hello, world!"); @endcode +and the somewhat less usual +@code +wxMessageBox(L"Salut \u00E0 toi!"); // U+00E0 is "Latin Small Letter a with Grave" +@endcode +work as expected. -What happens here? First of all, you see that there are no more UNICODE checks -at all. Instead, we define some types and macros which behave differently in -the Unicode and ANSI builds and allow us to avoid using conditional compilation -in the program itself. +Notice that the narrow strings used with wxWidgets are @e always assumed to be +in the current locale encoding, so writing +@code +wxMessageBox("Salut à toi!"); +@endcode +wouldn't work if the encoding used on the user system is incompatible with +ISO-8859-1 (or even if the sources were compiled under different locale +in the case of gcc). In particular, the most common encoding used under +modern Unix systems is UTF-8 and as the string above is not a valid UTF-8 byte +sequence, nothing would be displayed at all in this case. Thus it is important +to never use 8-bit (instead of 7-bit) characters directly in the program source +but use wide strings or, alternatively, write: +@code +wxMessageBox(wxString::FromUTF8("Salut \xC3\xA0 toi!")); + // in UTF8 the character U+00E0 is encoded as 0xC3A0 +@endcode -We have a @c wxChar type which maps either on @c char or @c wchar_t depending -on the mode in which program is being compiled. There is no need for a separate -type for strings though, because the standard wxString supports Unicode, i.e. -it stores either ANSI or Unicode strings depending on the compile mode. +In a similar way, wxString provides access to its contents as either @c wchar_t or +@c char character buffer. Of course, the latter only works if the string contains +data representable in the current locale encoding. This will always be the case +if the string had been initially constructed from a narrow string or if it +contains only 7-bit ASCII data but otherwise this conversion is not guaranteed +to succeed. And as with wxString::FromUTF8() example above, you can always use +wxString::ToUTF8() to retrieve the string contents in UTF-8 encoding -- this, +unlike converting to @c char* using the current locale, never fails. + +For more info about how wxString works, please see the @ref overview_string. + +To summarize, Unicode support in wxWidgets is mostly @b transparent for the +application and if you use wxString objects for storing all the character data +in your program there is really nothing special to do. However you should be +aware of the potential problems covered by the following section. + + +@section overview_unicode_pitfalls Potential Unicode Pitfalls + +The problems can be separated into three broad classes: + +@subsection overview_unicode_compilation_errors Unicode-Related Compilation Errors + +Because of the need to support implicit conversions to both @c char and +@c wchar_t, wxString implementation is rather involved and many of its operators +don't return the types which they could be naively expected to return. +For example, the @c operator[] doesn't return neither a @c char nor a @c wchar_t +but an object of a helper class wxUniChar or wxUniCharRef which is implicitly +convertible to either. Usually you don't need to worry about this as the +conversions do their work behind the scenes however in some cases it doesn't +work. Here are some examples, using a wxString object @c s and some integer @c +n: + + - Writing @code switch ( s[n] ) @endcode doesn't work because the argument of + the switch statement must be an integer expression so you need to replace + @c s[n] with @code s[n].GetValue() @endcode. You may also force the + conversion to @c char or @c wchar_t by using an explicit cast but beware that + converting the value to char uses the conversion to current locale and may + return 0 if it fails. Finally notice that writing @code (wxChar)s[n] @endcode + works both with wxWidgets 3.0 and previous library versions and so should be + used for writing code which should be compatible with both 2.8 and 3.0. + + - Similarly, @code &s[n] @endcode doesn't yield a pointer to char so you may + not pass it to functions expecting @c char* or @c wchar_t*. Consider using + string iterators instead if possible or replace this expression with + @code s.c_str() + n @endcode otherwise. + +Another class of problems is related to the fact that the value returned by +@c c_str() itself is also not just a pointer to a buffer but a value of helper +class wxCStrData which is implicitly convertible to both narrow and wide +strings. Again, this mostly will be unnoticeable but can result in some +problems: + + - You shouldn't pass @c c_str() result to vararg functions such as standard + @c printf(). Some compilers (notably g++) warn about this but even if they + don't, this @code printf("Hello, %s", s.c_str()) @endcode is not going to + work. It can be corrected in one of the following ways: + + - Preferred: @code wxPrintf("Hello, %s", s) @endcode (notice the absence + of @c c_str(), it is not needed at all with wxWidgets functions) + - Compatible with wxWidgets 2.8: @code wxPrintf("Hello, %s", s.c_str()) @endcode + - Using an explicit conversion to narrow, multibyte, string: + @code printf("Hello, %s", (const char *)s.mb_str()) @endcode + - Using a cast to force the issue (listed only for completeness): + @code printf("Hello, %s", (const char *)s.c_str()) @endcode + + - The result of @c c_str() cannot be cast to @c char* but only to @c const @c + @c char*. Of course, modifying the string via the pointer returned by this + method has never been possible but unfortunately it was occasionally useful + to use a @c const_cast here to pass the value to const-incorrect functions. + This can be done either using new wxString::char_str() (and matching + wchar_str()) method or by writing a double cast: + @code (char *)(const char *)s.c_str() @endcode + + - One of the unfortunate consequences of the possibility to pass wxString to + @c wxPrintf() without using @c c_str() is that it is now impossible to pass + the elements of unnamed enumerations to @c wxPrintf() and other similar + vararg functions, i.e. + @code + enum { Red, Green, Blue }; + wxPrintf("Red is %d", Red); + @endcode + doesn't compile. The easiest workaround is to give a name to the enum. + +Other unexpected compilation errors may arise but they should happen even more +rarely than the above-mentioned ones and the solution should usually be quite +simple: just use the explicit methods of wxUniChar and wxCStrData classes +instead of relying on their implicit conversions if the compiler can't choose +among them. + + +@subsection overview_unicode_data_loss Data Loss due To Unicode Conversion Errors + +wxString API provides implicit conversion of the internal Unicode string +contents to narrow, char strings. This can be very convenient and is absolutely +necessary for backwards compatibility with the existing code using wxWidgets +however it is a rather dangerous operation as it can easily give unexpected +results if the string contents isn't convertible to the current locale. + +To be precise, the conversion will always succeed if the string was created +from a narrow string initially. It will also succeed if the current encoding is +UTF-8 as all Unicode strings are representable in this encoding. However +initializing the string using wxString::FromUTF8() method and then accessing it +as a char string via its wxString::c_str() method is a recipe for disaster as the +program may work perfectly well during testing on Unix systems using UTF-8 locale +but completely fail under Windows where UTF-8 locales are never used because +wxString::c_str() would return an empty string. + +The simplest way to ensure that this doesn't happen is to avoid conversions to +@c char* completely by using wxString throughout your program. However if the +program never manipulates 8 bit strings internally, using @c char* pointers is +safe as well. So the existing code needs to be reviewed when upgrading to +wxWidgets 3.0 and the new code should be used with this in mind and ideally +avoiding implicit conversions to @c char*. + + +@subsection overview_unicode_performance Unicode Performance Implications + +Under Unix systems wxString class uses variable-width UTF-8 encoding for +internal representation and this implies that it can't guarantee constant-time +access to N-th element of the string any longer as to find the position of this +character in the string we have to examine all the preceding ones. Usually this +doesn't matter much because most algorithms used on the strings examine them +sequentially anyhow and because wxString implements a cache for iterating over +the string by index but it can have serious consequences for algorithms +using random access to string elements as they typically acquire O(N^2) time +complexity instead of O(N) where N is the length of the string. + +Even despite caching the index, indexed access should be replaced with +sequential access using string iterators. For example a typical loop: +@code +wxString s("hello"); +for ( size_t i = 0; i < s.length(); i++ ) +{ + wchar_t ch = s[i]; -Finally, there is a special wxT() macro which should enclose all literal -strings in the program. As it is easy to see comparing the last fragment with -the one above, this macro expands to nothing in the (usual) ANSI mode and -prefixes @c 'L' to its argument in the Unicode mode. + // do something with it +} +@endcode +should be rewritten as +@code +wxString s("hello"); +for ( wxString::const_iterator i = s.begin(); i != s.end(); ++i ) +{ + wchar_t ch = *i -The important conclusion is that if you use @c wxChar instead of @c char, avoid -using C style strings and use @c wxString instead and don't forget to enclose -all string literals inside wxT() macro, your program automatically becomes -(almost) Unicode compliant! + // do something with it +} +@endcode -Just let us state once again the rules: +Another, similar, alternative is to use pointer arithmetic: +@code +wxString s("hello"); +for ( const wchar_t *p = s.wc_str(); *p; p++ ) +{ + wchar_t ch = *i -@li Always use wxChar instead of @c char -@li Always enclose literal string constants in wxT() macro unless they're - already converted to the right representation (another standard wxWidgets - macro _() does it, for example, so there is no need for wxT() in this case) - or you intend to pass the constant directly to an external function which - doesn't accept wide-character strings. -@li Use wxString instead of C style strings. + // do something with it +} +@endcode +however this doesn't work correctly for strings with embedded @c NUL characters +and the use of iterators is generally preferred as they provide some run-time +checks (at least in debug build) unlike the raw pointers. But if you do use +them, it is better to use @c wchar_t pointers rather than @c char ones to avoid the +data loss problems due to conversion as discussed in the previous section. @section overview_unicode_supportout Unicode and the Outside World -We have seen that it was easy to write Unicode programs using wxWidgets types -and macros, but it has been also mentioned that it isn't quite enough. Although -everything works fine inside the program, things can get nasty when it tries to -communicate with the outside world which, sadly, often expects ANSI strings (a -notable exception is the entire Win32 API which accepts either Unicode or ANSI -strings and which thus makes it unnecessary to ever perform any conversions in -the program). GTK 2.0 only accepts UTF-8 strings. - -To get an ANSI string from a wxString, you may use the mb_str() function which -always returns an ANSI string (independently of the mode - while the usual -c_str() returns a pointer to the internal representation which is either ASCII -or Unicode). More rarely used, but still useful, is wc_str() function which -always returns the Unicode string. - -Sometimes it is also necessary to go from ANSI strings to wxStrings. In this -case, you can use the converter-constructor, as follows: - +Even though wxWidgets always uses Unicode internally, not all the other +libraries and programs do and even those that do use Unicode may use a +different encoding of it. So you need to be able to convert the data to various +representations and the wxString methods wxString::ToAscii(), wxString::ToUTF8() +(or its synonym wxString::utf8_str()), wxString::mb_str(), wxString::c_str() and +wxString::wc_str() can be used for this. + +The first of them should be only used for the string containing 7-bit ASCII characters +only, anything else will be replaced by some substitution character. +wxString::mb_str() converts the string to the encoding used by the current locale +and so can return an empty string if the string contains characters not representable in +it as explained in @ref overview_unicode_data_loss. The same applies to wxString::c_str() +if its result is used as a narrow string. Finally, wxString::ToUTF8() and wxString::wc_str() +functions never fail and always return a pointer to char string containing the +UTF-8 representation of the string or @c wchar_t string. + +wxString also provides two convenience functions: wxString::From8BitData() and +wxString::To8BitData(). They can be used to create a wxString from arbitrary binary +data without supposing that it is in current locale encoding, and then get it back, +again, without any conversion or, rather, undoing the conversion used by +wxString::From8BitData(). Because of this you should only use wxString::From8BitData() +for the strings created using wxString::To8BitData(). Also notice that in spite +of the availability of these functions, wxString is not the ideal class for storing +arbitrary binary data as they can take up to 4 times more space than needed +(when using @c wchar_t internal representation on the systems where size of +wide characters is 4 bytes) and you should consider using wxMemoryBuffer +instead. + +Final word of caution: most of these functions may return either directly the +pointer to internal string buffer or a temporary wxCharBuffer or wxWCharBuffer +object. Such objects are implicitly convertible to @c char and @c wchar_t pointers, +respectively, and so the result of, for example, wxString::ToUTF8() can always be +passed directly to a function taking const char*. However code such as @code -const char* ascii_str = "Some text"; -wxString str(ascii_str, wxConvUTF8); +const char *p = s.ToUTF8(); +... +puts(p); // or call any other function taking const char * @endcode +does @b not work because the temporary buffer returned by wxString::ToUTF8() is +destroyed and @c p is left pointing nowhere. To correct this you should use +@code +const wxScopedCharBuffer p(s.ToUTF8()); +puts(p); +@endcode +which does work. -This code also compiles fine under a non-Unicode build of wxWidgets, but in -that case the converter is ignored. - -For more information about converters and Unicode see the @ref overview_mbconv. - +Similarly, wxWX2WCbuf can be used for the return type of wxString::wc_str(). +But, once again, none of these cryptic types is really needed if you just pass +the return value of any of the functions mentioned in this section to another +function directly. @section overview_unicode_settings Unicode Related Compilation Settings -You should define @c wxUSE_UNICODE to 1 to compile your program in Unicode -mode. This currently works for wxMSW, wxGTK, wxMac and wxX11. If you compile -your program in ANSI mode you can still define @c wxUSE_WCHAR_T to get some -limited support for @c wchar_t type. - -This will allow your program to perform conversions between Unicode strings and -ANSI ones (using @ref overview_mbconv "wxMBConv") and construct wxString -objects from Unicode strings (presumably read from some external file or -elsewhere). - - -@section overview_unicode_traps Traps for the Unwary +@c wxUSE_UNICODE is now defined as @c 1 by default to indicate Unicode support. +If UTF-8 is used for the internal storage in wxString, @c wxUSE_UNICODE_UTF8 is +also defined, otherwise @c wxUSE_UNICODE_WCHAR is. -@li Casting c_str() to void* is now char*, not wxChar* -@li Passing c_str(), mb_str() or wc_str() to variadic functions doesn't work. +You are encouraged to always use the default build settings of wxWidgets; this avoids +the need of different builds of the same application/library because of different +"build modes". */