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I am developing a cross platform C (C89 standard) application which has to deal with UTF8 text. All I need is basic string manipulation functions like substr, first, last etc.

Question 1

Is there a UTF8 library that has the above functions implemented? I have already looked into ICU and it is too big for my requirement. I just need to support UTF8.

I have found a UTF8 decoder here. Following function prototypes are from that code.

void utf8_decode_init(char p[], int length);

int utf8_decode_next();

The initialization function takes a character array but utf8_decode_next() returns int. Why is that? How can I print the characters this function returns using standard functions like printf? The function is dealing with character data and how can that be assigned to a integer?

If the above decoder is not good for production code, do you have a better recommendation?

Question 2

I also got confused by reading articles that says, for unicode you need to use wchar_t. From my understanding this is not required as normal C strings can hold UTF8 values. I have verified this by looking at source code of SQLite and git. SQLite has the following typedef.

typedef unsigned char u8

Is my understanding correct? Also why is unsigned char required?

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6 Answers 6

up vote 4 down vote accepted
  1. The utf_decode_next() function returns the next Unicode code point. Since Unicode is a 21-bit character set, it cannot return anything smaller than an int, and it can be argued that technically, it should be a long since an int could be a 16-bit quantity. Effectively, the function returns you a UTF-32 character.

    You would need to look at the C94 wide character extensions to C89 to print wide characters (wprintf(), <wctype.h>, <wchar.h>). However, wide characters alone are not guaranteed to be UTF-8 or even Unicode. You most probably cannot print the characters from utf8_decode_next() portably, but it depends on what your portability requirements are. The wider the range of systems you must port to, the less chance there is of it all working simply. To the extent you can write UTF-8 portably, you would send the UTF-8 string (not an array of the UTF-32 characters obtained from utf8_decode_next()) to one of the regular printing functions. One of the strengths of UTF-8 is that it can be manipulated by code that is largely ignorant of it.

  2. You need to understand that a 4-byte wchar_t can hold any Unicode codepoint in a single unit, but that UTF-8 can require between one and four 8-bit bytes (1-4 units of storage) to hold a single Unicode codepoint. On some systems, I believe wchar_t can be a 16-bit (short) integer. In this case, you are forced into using UTF-16, which encodes Unicode codepoints outside the Basic Multilingual Plane (BMP, code points U+0000 .. U+FFFF) using two storage units and surrogates.

    Using unsigned char makes life easier; plain char is often signed. Having negative numbers makes life more difficult than it need me (and, believe me, it is difficult enough without adding complexity).

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int32_t would be the preferred type for Unicode codepoints. As you say, int could in theory be to short, and long will certainly be a huge waste of space on any 64-bit machine. –  R.. Dec 21 '10 at 20:45
    
@R..: Fair comment; and with only the less-significant 21 of the 32 bits in use, there's no need to worry about uint32_t vs int32_t. –  Jonathan Leffler Dec 21 '10 at 20:58
    
I like using a signed type in order to easily be able to use negative values for errors, but during decoding, unsigned types are often more convenient. It really doesn't matter which you use as long as it's a 32-bit type, as you said. –  R.. Dec 21 '10 at 22:34
    
It's a crying shame that few implementations provide int_least22_t. What are they thinking? –  Steve Jessop Dec 22 '10 at 10:50
    
Thanks @Jonathan. I have implemented substr and length and not used the above decoder. It looks like the new implementation is more simple. It is posted here. stackoverflow.com/questions/4501621/… –  Appu Dec 26 '10 at 15:31

You do not need any special library routines for character or substring search with UTF-8. strstr does everything you need. That's the whole point of UTF-8 and the design requirements it was invented to meet.

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@R.. Thanks. So just to understand, strstr has a UTF8 decoder? –  Appu Dec 22 '10 at 4:35
1  
No, because it doesn't need one. That is the whole point of UTF-8. –  R.. Dec 22 '10 at 4:47
    
thanks a lot. I am sorry but I am still bit confused. As per my understanding, since UTF8 is not subjected to byte ordering, comparing the bytes itself will give correct information and you don't need to decode it. That's why strstr is working with UTF8. Is that correct? –  Appu Dec 22 '10 at 6:41
    
Suppose you're looking for the string "Áx", represented as the bytes C3 81 78 (hex) in the string "ÄÁxy" represented as the bytes C3 84 C3 81 78 79. How do you find it? Just look for the sequence of bytes; you find it at byte offset 2. This is how strstr works. Note that while both Ä and Á begin with C3, no character can ever be a substring of another character in UTF-8. –  R.. Dec 22 '10 at 6:52
2  
Characters in (valid) UTF-8 always start with a head byte 00-7F or C2-F4 and continue for all following bytes in the range 80-BF. If you want the last character, you can start at the last byte and work backwards until you find a head-byte. On the other hand, if you know a particular character you're looking for, just compare that many bytes at the end of the string with the bytes of that character and see if they match. If so, write a null byte over top of the first one and you've removed it. –  R.. Dec 23 '10 at 4:48

GLib has quite a few relevant functions, and can be used independent of GTK+.

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can I compile this on windows? –  Appu Dec 22 '10 at 4:17
    
Sure, but it's probably already compiled. You just need to grab the DLL, headers, and import libs. gtk.org/download-windows.html –  Ignacio Vazquez-Abrams Dec 22 '10 at 4:18

There are over 100,000 characters in Unicode. There are 256 possible values of char in most C implementations.

Hence, UTF-8 uses more than one char to encode each character, and the decoder needs a return type which is larger than char.

wchar_t is a larger type than char (well, it doesn't have to be larger, but it usually is). It represents the characters of the implementation-defined wide character set. On some implementations (most importantly, Windows, which uses surrogate pairs for characters outside the "basic multilingual plane"), it still isn't big enough to represent any Unicode character, which presumably is why the decoder you reference uses int.

You can't print wide characters using printf, because it deals in char. wprintf deals in wchar_t, so if the wide character set is unicode, and if wchar_t is int on your system (as it is on linux), then wprintf and friends will print the decoder output without further processing. Otherwise it won't.

In any case, you cannot portably print arbitrary unicode characters, because there's no guarantee that the terminal can display them, or even that the wide character set is in any way related to Unicode.

SQLite has probably used unsigned char so that:

  • they know the signedness - it's implementation-defined whether char is signed or not.
  • they can do right-shifts and assign out-of-range values, and get consistent and defined results across all C implementations. Implemenations have more freedom how signed char behaves than unsigned char.
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Thanks. So it doesn't make sense to use wchar_t right? –  Appu Dec 21 '10 at 17:10
    
@Appu: depends what the platforms are that you want to support, and whether you need to support all of Unicode or just the BMP, but probably not. –  Steve Jessop Dec 21 '10 at 17:16

Normal C strings are fine for storing utf8 data, but you can't easily search for a substring in your utf8 string. This is because a character encoded as a sequence of bytes using the utf8 encoding could be anywhere from one to 4 bytes depending on the character. i.e. a "character" is not equivalent to a "byte" for utf8 like it is for ASCII.

In order to do substring searches etc. you will need to decode it to some internal format that is used to represent Unicode characters and then do the substring search on that. Since there are far more than Unicode 256 characters, a byte (or char) is not enough. That's why the library you found uses ints.

As for your second question, it's probably just because it does not make sense to talk about negative characters, so they may as well be specified as "unsigned".

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5  
You can do substring searches in UTF-8 data just by looking for a matching sequence of bytes, provided that the UTF-8 data uses the canonical representation for each character (if not canonical, you can get false negatives). UTF-8 is cunningly designed to prevent false positives: you can tell by the top bits whether a given byte is the first byte of a character or not, so neither a subsequence of a character, nor the end of one character followed by the beginning of another, can possibly be confused for a different character. –  Steve Jessop Dec 21 '10 at 17:15
    
@Wodin: Your answer is horribly wrong. @Steve: Each character has a unique representation in UTF-8. There are no non-canonical representations of characters, but there are multiple sequences of characters which are "canonically equivalent" to one another under Unicode - precomposed versus composing forms, and such. Whether you want to process or ignore these equivalences probably depends on what you're doing. –  R.. Dec 21 '10 at 20:48
    
@R..: there aren't supposed to be non-canonical representations, but some utf-8 decoders behave as if there are, e.g. decoding 11000000 10000001 to U+01, so that you check your "UTF-8" input for 0x01, think there aren't any, but later decode it and there are. So it depends how pedantic your decoder is or how trusted your input is. And yes, combining characters are also tricky so in practice if you can get away with defining equivalent sequences non-equal, you do. As you say, that's a general unicode issue, not utf-8 in particular. –  Steve Jessop Dec 21 '10 at 21:41
    
Maybe this isn't an issue any more - if the last such non-verifying decoder has been put to pasture... –  Steve Jessop Dec 21 '10 at 22:19
1  
@Steve: Any decoder that decodes what you're calling non-canonical representations is non-conforming and extremely dangerous. If there's any such code in your project you should purge it immediately. In particular, the bytes 0xC0 and 0xC1 (along with 0xF5...0xFF) are completely invalid in UTF-8 and must always be rejected. There are certain other sequences which must be rejected too. UTF-8 decoding is best handled by a DFA, not traditional loops which are error-prone and tend to decode invalid inputs as aliases for valid strings. –  R.. Dec 21 '10 at 22:32

I have implemented a substr & length functions which supports UTF8 characters. This code is a modified version of what SQLite uses.

The following macro loops through the input text and skip all multi-byte sequence characters. if condition checks that this is a multi-byte sequence and the loop inside it increments input until it finds next head byte.

#define SKIP_MULTI_BYTE_SEQUENCE(input) {              \
    if( (*(input++)) >= 0xc0 ) {                       \ 
    while( (*input & 0xc0) == 0x80 ){ input++; }       \
  }                                                    \
}

substr and length are implemented using this macro.

typedef unsigned char utf8;

substr

void *substr(const utf8 *string, 
             int start, 
             int len, 
             utf8 **substring)
{
    int bytes, i;
    const utf8 *str2;
    utf8 *output;

    --start;
    while( *string && start ) {
        SKIP_MULTI_BYTE_SEQUENCE(string);
        --start;
    }

    for(str2 = string; *str2 && len; len--) {
        SKIP_MULTI_BYTE_SEQUENCE(str2);
    }

    bytes = (int) (str2 - string);
    output = *substring;
    for(i = 0; i < bytes; i++) {
        *output++ = *string++;
    }
    *output = '\0';
}

length

int length(const utf8 *string)
{
    int len;
    len = 0;
    while( *string ) {
        ++len;
        SKIP_MULTI_BYTE_SEQUENCE(string);
    }
    return len;
}
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error checking is omitted for clarity –  Appu Dec 26 '10 at 15:44

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