How to iterate through unicode characters and print them on the screen with printf in C?

后端 未结 4 1208
不知归路
不知归路 2021-01-05 21:00

I want to iterate through all (at least the 16 bit) unicode characters and print them on the screen with C.

I know there are related questions on SO but they don\'t

相关标签:
4条回答
  • 2021-01-05 21:16

    If the __STDC_ISO_10646__ macro is defined, wide characters correspond to Unicode codepoints. So, assuming a locale that can represent the characters you are interested in, you can just printf() wide characters via the %lc format conversion:

    #include <stdio.h>
    #include <locale.h>
    
    #ifndef __STDC_ISO_10646__
    #error "Oops, our wide chars are not Unicode codepoints, sorry!"
    #endif
    int main()
    {
            int i;
            setlocale(LC_ALL, "");
    
            for (i = 0; i < 0xffff; i++) {
                    printf("%x - %lc\n", i, i);
            }
    
            return 0;
    }
    
    0 讨论(0)
  • 2021-01-05 21:21

    In C99, you can use wide character to multibyte character conversion functions wctomb() or wcrtomb() to convert each code point to a local representation, using the current character set. (The code points are in the current character set, not Unicode.) Remember to use setlocale() to ensure conversion functions are aware of the user locale (most importantly, the current character set used). The conversion functions use the LC_CTYPE category, but you should still use setlocale(LC_ALL, ""); as for any other locale-aware program.

    (Not all systems have the C.UTF-8 locale installed, so I do not recommend trying to override the locale to the standard C with UTF-8 using setlocale(LC_ALL, "C.UTF-8");. It works on some systems, but not all. AFAIK it does not work in Fedora-based Linux distributions, for example.)

    Because you want to output all Unicode code points, I suggest a different approach: Use one of the Universal Character Set Transformation Formats, i.e. UTF-8, UTF-16 (UCS-2 was superseded by UTF-16 in 1996), or UTF-32 (also known as UCS-4). UTF-8 is the one most often used on the Web -- in particular, on this very web page you're looking at right now -- and is very easy to use.

    For further reading on why you should prefer UTF-8 over "native wide strings", see utf8everywhere.org.

    If you want truly portable code, you can use this header file, utf8.h, to convert UTF-8 to unicode code points (utf8_to_code()) and Unicode code points to UTF-8 (code_to_utf8()):

    #ifndef   UTF8_H
    #define   UTF8_H
    #include <stdlib.h>
    #include <errno.h>
    
    #define   UTF8_MAXLEN 6
    
    static size_t utf8_to_code(const unsigned char *const buffer, unsigned int *const codeptr)
    {
        if (!buffer) {
            errno = EINVAL;
            return 0;
        }
    
        if (*buffer == 0U) {
            errno = 0;
            return 0;
        }
    
        if (*buffer < 128U) {
            if (codeptr)
                *codeptr = buffer[0];
            return 1;
        }
    
        if (*buffer < 192U) {
            errno = EILSEQ;
            return 0;
        }
    
        if (*buffer < 224U) {
            if (buffer[1] >= 128U && buffer[1] < 192U)
                return ((buffer[0] - 192U) << 6U)
                     |  (buffer[1] - 128U);
            errno = EILSEQ;
            return 0;
        }
    
        if (*buffer < 240U) {
            if (buffer[1] >= 128U && buffer[1] < 192U &&
                buffer[2] >= 128U && buffer[2] < 192U)
                return ((buffer[0] - 224U) << 12U)
                     | ((buffer[1] - 128U) << 6U)
                     |  (buffer[2] - 128U);
            errno = EILSEQ;
            return 0;
        }
    
        if (*buffer < 248U) {
            if (buffer[1] >= 128U && buffer[1] < 192U &&
                buffer[2] >= 128U && buffer[2] < 192U &&
                buffer[3] >= 128U && buffer[3] < 192U)
                return ((buffer[0] - 240U) << 18U)
                     | ((buffer[1] - 128U) << 12U)
                     | ((buffer[2] - 128U) << 6U)
                     |  (buffer[3] - 128U);
            errno = EILSEQ;
            return 0;
        }
    
        if (*buffer < 252U) {
            if (buffer[1] >= 128U && buffer[1] < 192U &&
                buffer[2] >= 128U && buffer[2] < 192U &&
                buffer[3] >= 128U && buffer[3] < 192U &&
                buffer[4] >= 128U && buffer[4] < 192U)
                return ((buffer[0] - 248U) << 24U)
                     | ((buffer[1] - 128U) << 18U)
                     | ((buffer[2] - 128U) << 12U)
                     | ((buffer[3] - 128U) << 6U)
                     |  (buffer[4] - 128U);
            errno = EILSEQ;
            return 0;
        }
    
        if (*buffer < 254U) {
            if (buffer[1] >= 128U && buffer[1] < 192U &&
                buffer[2] >= 128U && buffer[2] < 192U &&
                buffer[3] >= 128U && buffer[3] < 192U &&
                buffer[4] >= 128U && buffer[4] < 192U &&
                buffer[5] >= 128U && buffer[5] < 192U)
                return ((buffer[0] - 252U) << 30U)
                     | ((buffer[1] - 128U) << 24U)
                     | ((buffer[2] - 128U) << 18U)
                     | ((buffer[3] - 128U) << 12U)
                     | ((buffer[4] - 128U) << 6U)
                     |  (buffer[5] - 128U);
            errno = EILSEQ;
            return 0;
        }
    
        errno = EILSEQ;
        return 0;
    }
    
    static size_t code_to_utf8(unsigned char *const buffer, const unsigned int code)
    {
        if (code < 128U) {
            buffer[0] = code;
            return 1;
        }
        if (code < 2048U) {
            buffer[0] = 0xC0U | (code >> 6U);
            buffer[1] = 0x80U | (code & 0x3FU);
            return 2;
        }
        if (code < 65536) {
            buffer[0] = 0xE0U | (code >> 12U);
            buffer[1] = 0x80U | ((code >> 6U) & 0x3FU);
            buffer[2] = 0x80U | (code & 0x3FU);
            return 3;
        }
        if (code < 2097152U) {
            buffer[0] = 0xF0U | (code >> 18U);
            buffer[1] = 0x80U | ((code >> 12U) & 0x3FU);
            buffer[2] = 0x80U | ((code >> 6U) & 0x3FU);
            buffer[3] = 0x80U | (code & 0x3FU);
            return 4;
        }
        if (code < 67108864U) {
            buffer[0] = 0xF8U | (code >> 24U);
            buffer[1] = 0x80U | ((code >> 18U) & 0x3FU);
            buffer[2] = 0x80U | ((code >> 12U) & 0x3FU);
            buffer[3] = 0x80U | ((code >> 6U) & 0x3FU);
            buffer[4] = 0x80U | (code & 0x3FU);
            return 5;
        }
        if (code <= 2147483647U) {
            buffer[0] = 0xFCU | (code >> 30U);
            buffer[1] = 0x80U | ((code >> 24U) & 0x3FU);
            buffer[2] = 0x80U | ((code >> 18U) & 0x3FU);
            buffer[3] = 0x80U | ((code >> 12U) & 0x3FU);
            buffer[4] = 0x80U | ((code >> 6U) & 0x3FU);
            buffer[5] = 0x80U | (code & 0x3FU);
            return 6;
        }
        errno = EINVAL;
        return 0;
    }
    
    #endif /* UTF8_H */
    

    It is not fast, but it should be easy to understand, and supports all possible Unicode code points (U+0000 to U+10FFFF, inclusive), on all systems with at least 32-bit unsigned ints. On systems with 16-bit unsigned ints, your compiler may warn about unreachable code, and it'll only support the first 65536 code points (U+0000 to U+FFFF).

    Using above utf8.h, you can easily write a C program that outputs a HTML page containing the Unicode characters you want (excluding control characters U+0000-U+001F and U+007F-U+00BF, inclusive, and invalid code points U+D800-U+DFFF, inclusive). For example, page.c:

    #include <stdlib.h>
    #include <stdio.h>
    #include <errno.h>
    #include "utf8.h"
    
    int main(void)
    {
        unsigned char  ch[UTF8_MAXLEN + 1];
        unsigned int   i;
        const char    *str;
        size_t         n, len;
    
        /* HTML5 DOCTYPE */
        printf("<!DOCTYPE html>\n");
        printf("<html>\n");
    
        /* Header part. */
        printf(" <head>\n");
        printf("  <title> Unicode character list </title>\n");
        printf("  <meta http-equiv=\"Content-Type\" content=\"text/html; charset=UTF-8\">\n");
        printf("  <style type=\"text/css\">\n");
        /* with internal CSS stylesheet: */
        printf("   html {\n");
        printf("    font-family: \"DejaVu Mono\", \"Courier New\", \"Courier\", monospace;\n");
        printf("    font-weight: normal;\n");
        printf("    font-size: 100%%;\n");
        printf("    text-decoration: none;\n");
        printf("    background: #f7f7f7;\n");
        printf("    color: #000000;\n");
        printf("    padding: 0 0 0 0;\n");
        printf("    border: 0 none;\n");
        printf("    margin: 0 0 0 0\n");
        printf("   }\n");
    
        printf("   body {\n");
        printf("    background: #ffffff;\n");
        printf("    padding: 0.5em 1em 0.5em 1em;\n");
        printf("    border: 1px solid #cccccc;\n");
        printf("    margin: 0 auto auto auto;\n");
        printf("    width: 12em;\n");
        printf("    text-align: center;\n");
        printf("   }\n");
    
        printf("   p {\n");
        printf("    padding: 0 0 0 0;\n");
        printf("    border: 0 none;\n");
        printf("    margin: 0 0 0 0;\n");
        printf("    outline: 0 none;\n");
        printf("    text-align: center;\n");
        printf("   }\n");
    
        printf("   p.odd {\n");
        printf("    background: #efefef;\n");
        printf("   }\n");
    
        printf("   p.even {\n");
        printf("    background: #f7f7f7;\n");
        printf("   }\n");
    
        printf("   span.code {\n");
        printf("    width: 8em;\n");
        printf("    text-align: right;\n");
        printf("   }\n");
    
        printf("   span.char {\n");
        printf("    width: 4em;\n");
        printf("    text-align: left;\n");
        printf("   }\n");
    
        printf("  </style>\n");
        printf(" </head>\n");
    
        /* Body part. */
        printf(" <body>\n");
    
        n = 0;
        for (i = 0U; i <= 0xFFFFU; i++) {
    
            /* Skip Unicode control characters. */
            if ((i >= 0U && i <= 31U) ||
                (i >= 127U && i <= 159U))
                continue;
    
            /* Skip invalid Unicode code points. */
            if (i >= 0xD800U && i <= 0xDFFFU)
                continue;
    
            len = code_to_utf8(ch, i);
            if (len > 0) {
                ch[len] = '\0';
    
                /* HTML does not like " & < > */
                if (i == 32U)
                    str = "&nbsp;";
                else
                if (i == 34U)
                    str = "&#34;";
                else
                if (i == 38U)
                    str = "&amp;";
                else
                if (i == 60U)
                    str = "&lt;";
                else
                if (i == 62U)
                    str = "&gt;";
                else
                    str = (const char *)ch;
    
                if (n & 1) {
                printf("  <p class=\"odd\" title=\"%u in decimal, &amp;#%u; = %s\">", i, i, str);
                    printf("<span class=\"code\">U+%04X</span>", i);
                    printf(" <span class=\"char\">%s</span>", str);
                    printf("</p>\n");
                } else {
                    printf("  <p class=\"even\" title=\"%u in decimal, &amp;#%u; = %s\">", i, i, str);
                    printf("<span class=\"code\">U+%04X</span>", i);
                    printf(" <span class=\"char\">%s</span>", str);
                    printf("</p>\n");
                }
    
                n++;
            }
        }
    
        printf(" </body>\n");
        printf("</html>\n");
    
        return EXIT_SUCCESS;
    }
    

    Redirect the output to a file, and you can open the file in whatever browser you prefer. If your browser is sane, and does not treat local files any different to those it obtains from a web server, then you should see the correct output.

    (If you see multiple characters per code point after U+00A0, your browser has decided that because the file is local, it is using a different character set that it explicitly states it uses. Switch to a sane browser if that happens, or override the character set selection.)

    If you want, you can just print the codes out as UTF-8 text, say using text.c:

    #include <stdlib.h>
    #include <stdio.h>
    #include <errno.h>
    #include "utf8.h"
    
    int main(void)
    {
        unsigned char  ch[UTF8_MAXLEN + 1];
        unsigned int   i;
        size_t         len;
    
        for (i = 0U; i <= 0xFFFFU; i++) {
    
            /* Skip Unicode control characters. */
            if ((i >= 0U && i <= 31U) ||
                (i >= 127U && i <= 159U))
                continue;
    
            /* Skip invalid Unicode code points. */
            if (i >= 0xD800U && i <= 0xDFFFU)
                continue;
    
            len = code_to_utf8(ch, i);
            if (len > 0) {
                ch[len] = '\0';
                printf("U+%04X %s \n", i, ch);
            }
        }
    
        return EXIT_SUCCESS;
    }
    

    but then you must either be sure your terminal or terminal emulator supports UTF-8 and uses an UTF-8 locale, or you redirect the output to a text file and open that file in an editor which either assumes the file uses UTF-8 or lets you explicitly select the UTF-8 character set.

    Note that there is a space before and after each character. Because some of the code points are combining characters, they may not show up at all unless they can be combined with another character, and most (all?) combine with space just fine.

    If you use Windows, then you must conform to Microsoft stupidity, and add a special "byte order mark" -- printf("\xEF\xBB\xBF"); -- to the beginning of the output, so that its utilities like Notepad recognizes the file as UTF-8. It's a Windows-only wart, and treat it as such.

    Questions?

    0 讨论(0)
  • 2021-01-05 21:38

    I would go for something like this (using raw UTF-8 encoding):

    char unicode[3] = { 0x00, 0x00, 0x00 };
    for(size_t i=0; i<0xffff; i++)
    {
        printf("%s\n", unicode);
        uint16_t * code = &unicode[0];
        *code = *code +1;
    }
    
    • Define a string on 3 bytes, the last one is the NULL terminating byte allowing a display via printf
    • Consider the two first bytes as your 16-bit unicode and increment it on each loop

    Of course it can be optimized as:

    • Many characters won't be displayable
    • The cast char* -> uint16_t is not very elegant (triggers a warning)
    • As there is 2 bytes for UTF-8 encoding it will actually browse 11 bits of codepoints. To get the 16 bits you might want to actually use uint32_t and define a 5 bytes char* buffer

    [EDIT] As stated in the comment, this loop will actually generates a lot of invalid UTF-8 sequences. Indeed, going from U+007F to U+0080 is a +1 for code points but in UTF-8 you jump from 0x7F to 0xC280: you need to exclude some ranges in the loop.

    0 讨论(0)
  • 2021-01-05 21:43

    The function to convert a 16-bit Unicode codepoint to a multibyte character sequence is c16rtomb; there is also c32rtomb if you want to handle 32-bit codepoints:

    #include <uchar.h>
    
    mbstate_t ps;
    char buf[MB_CUR_MAX];
    size_t bytes = c16rtomb(buf, i, &ps);
    if (bytes != (size_t) -1) {
      printf("%.*s\n", bytes, buf);
    }
    

    If c16rtomb is not available you will need to use platform-specific facilities.

    0 讨论(0)
提交回复
热议问题