I can't think of a way to remove the leading zeros. My goal was in a for loop to then create the UTF-8 and UTF-32 versions of each number.

For example, with UTF-8 wouldn't I have to remove the leading zeros? Does anyone have a solution for how to pull this off? Basically what I am asking is: does someone have a easy solution to convert Unicode code points to UTF-8?

    for (i = 0x0; i < 0xffff; i++) {
        printf("%#x \n", i);
        //convert to UTF8

So here is an example of what I am trying to accomplish for each i.

  • For example: Unicode value U+0760 (Base 16) would convert to UTF8 as
    • in binary: 1101 1101 1010 0000
    • in hex: DD A0

Basically I am trying to do that for every i is convert it to its hex equivalent in UTF-8.

The problem I am running into is it seems the process for converting Unicode to UTF-8 involves removing leading 0s from the bit number. I am not really sure how to do that dynamically.

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  • When you say "of each number" do you mean that the integer 1234 will produce the string "1234" UTF-8 encoded? Or do you mean it will produce the character represented by 1234 in UTF-8? (Spoiler: there isn't one) Or do you mean the 1234th Unicode code point? – Schwern Feb 2 '17 at 21:28
  • @Schwern my goal was to convert all Unicode characters 0x0 to 0x10FFFF to UTF8 and UTF32 form.. – Joe Caraccio Feb 2 '17 at 21:30
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    That's still ambiguous. Could you give a solid example? And did you mean 0x0 to 0xFFFF? That's what your code is doing. – Schwern Feb 2 '17 at 21:30
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    There are many ways to convert code-points 0 to 10FFFF to a small sequence of bytes for UTF-8. Of course the surrogates do not convert. – chux - Reinstate Monica Feb 2 '17 at 21:37
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    en.wikipedia.org/wiki/UTF-8 – Jens Gustedt Feb 2 '17 at 21:38

As the Wikipedia UTF-8 page describes, each Unicode code point (0 through 0x10FFFF) is encoded in UTF-8 character as one to four bytes.

Here is a simple example function, edited from one of my earlier posts. I've now removed the U suffixes from the integer constants too. (.. whose intent was to remind the human programmer that the constants are explicitly unsigned for a reason (negative code points not considered at all), and it does assume unsigned int code -- the compiler does not care, and probably because of that this practice seems to be odd and confusing even to long-term members here, so I give up and stop trying to include such reminders. :( )

static size_t code_to_utf8(unsigned char *const buffer, const unsigned int code)
    if (code <= 0x7F) {
        buffer[0] = code;
        return 1;
    if (code <= 0x7FF) {
        buffer[0] = 0xC0 | (code >> 6);            /* 110xxxxx */
        buffer[1] = 0x80 | (code & 0x3F);          /* 10xxxxxx */
        return 2;
    if (code <= 0xFFFF) {
        buffer[0] = 0xE0 | (code >> 12);           /* 1110xxxx */
        buffer[1] = 0x80 | ((code >> 6) & 0x3F);   /* 10xxxxxx */
        buffer[2] = 0x80 | (code & 0x3F);          /* 10xxxxxx */
        return 3;
    if (code <= 0x10FFFF) {
        buffer[0] = 0xF0 | (code >> 18);           /* 11110xxx */
        buffer[1] = 0x80 | ((code >> 12) & 0x3F);  /* 10xxxxxx */
        buffer[2] = 0x80 | ((code >> 6) & 0x3F);   /* 10xxxxxx */
        buffer[3] = 0x80 | (code & 0x3F);          /* 10xxxxxx */
        return 4;
    return 0;

You supply it with an unsigned char array, four chars or larger, and the Unicode code point. The function will return how many chars were needed to encode the code point in UTF-8, and were assigned in the array. The function will return 0 (not encoded) for codes above 0x10FFFF, but it does not otherwise check that the Unicode code point is valid. Ie. it is a simple encoder, and all it knows about Unicode is that the code points are from 0 to 0x10FFFF, inclusive. It knows nothing about surrogate pairs, for example.

Note that because the code point is explicitly an unsigned integer, negative arguments will be converted to unsigned according to C rules.

You need to write a function that prints out the least 8 significant bits in each unsigned char (the C standard does allow larger char sizes, but UTF-8 only uses 8-bit chars). Then, use the above function to convert an Unicode code point (0 to 0x10FFFF, inclusive) to UTF-8 representation, and call your bit function for each unsigned char in the array, in increasing order, for the count of unsigned char the above conversion function returned for that code point.

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  • All these U suffixes on the integral literals are redundant and confusing. They are not needed for the unsigned argument type. Btw: I don't know why you did not use the suffix for 0xFFFF and 0x10FFFF, but removing them everywhere would IMHO improve readability. – chqrlie Feb 4 '17 at 14:44
  • @chqrlie: See comments here. If I remove them, I'll remove the "hint" (wrt. behaviour change if you switch the parameter to int code). Eff it, it's not worth the effort. Will edit. – Nominal Animal Feb 4 '17 at 15:20
  • indeed not worth it, chux updated his own answer and removed the U suffixes too. – chqrlie Feb 4 '17 at 15:48
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    @chqrlie: No, chux never had them. I do like them myself, because they tell me that there is a specific reason (although not what that reason is) for the unsignedness. I need to find a better way to include such hints, that certain modifications may include unexpected side effects that are intentionally avoided by the current form of the code. I do believe they help those who read and experiment with the code in order to learn from it. Also, such error-inducing changes are a form of "trap" to those who simply take code and modify it minimally to present as their own coursework. Suggestions? – Nominal Animal Feb 4 '17 at 18:42
  • (In any larger project or production code, I include such assumptions and choices in comment blocks before the implementation; interface choices and reasons for them in comment blocks before the declaration. Of course, there is no sense in any kind of "traps" then. I do try to keep a big difference between learning examples and actual production stuff.) – Nominal Animal Feb 4 '17 at 18:45

Converting to UTF-32 is trivial, it's just the Unicode code point.

#include <wchar.h>

wint_t codepoint_to_utf32( const wint_t codepoint ) {
    if( codepoint > 0x10FFFF ) {
        fprintf( stderr, "Codepoint %x is out of UTF-32 range\n", codepoint);
        return -1;

    return codepoint;

Note that I'm using wint_t, w for "wide". That's an integer which is guaranteed to be large enough to hold any wchar_t as well as EOF. wchar_t (wide character) is guaranteed to be wide enough to support all system locales.

Converting to UTF-8 is a bit more complicated because of its codepage layout designed to be compatible with 7-bit ASCII. Some bit shifting is required.

Start with the UTF-8 table.

U+0000  U+007F    0xxxxxxx
U+0080  U+07FF    110xxxxx  10xxxxxx
U+0800  U+FFFF    1110xxxx  10xxxxxx    10xxxxxx
U+10000 U+10FFFF  11110xxx  10xxxxxx    10xxxxxx    10xxxxxx

Turn that into a big if/else if statement.

wint_t codepoint_to_utf8( const wint_t codepoint ) {
    wint_t utf8 = 0;

    // U+0000   U+007F    0xxxxxxx
    if( codepoint <= 0x007F ) {
    // U+0080   U+07FF    110xxxxx  10xxxxxx
    else if( codepoint <= 0x07FF ) {
    // U+0800   U+FFFF    1110xxxx  10xxxxxx    10xxxxxx
    else if( codepoint <= 0xFFFF ) {
    // U+10000  U+10FFFF  11110xxx  10xxxxxx    10xxxxxx    10xxxxxx
    else if( codepoint <= 0x10FFFF ) {
    else {
        fprintf( stderr, "Codepoint %x is out of UTF-8 range\n", codepoint);
        return -1;

    return utf8;

And start filling in the blanks. The first one is easy, it's just the code point.

    // U+0000   U+007F    0xxxxxxx
    if( codepoint <= 0x007F ) {
        utf8 = codepoint;

To do the next one, we need to apply a bit mask and do some bit shifting. C doesn't support binary literals, so I converted the binary into hex using perl -wle 'printf("%x\n", 0b1100000010000000)'

    // U+0080   U+07FF    110xxxxx  10xxxxxx
    else if( codepoint <= 0x00007FF ) {
        // Start at 1100000010000000
        utf8 = 0xC080;

        // 6 low bits using the bitmask 00111111
        // That fills in the 10xxxxxx part.
        utf8 += codepoint & 0x3f;

        // 5 high bits using the bitmask 11111000000
        // Shift over 2 to jump the hard coded 10 in the low byte.
        // That fills in the 110xxxxx part.
        utf8 += (codepoint & 0x7c0) << 2;

I'll leave the rest to you.

We can test this with various interesting values that touch each piece of logic.

int main() {    
    // https://codepoints.net/U+0041
    printf("LATIN CAPITAL LETTER A: %x\n", codepoint_to_utf8(0x0041));
    // https://codepoints.net/U+00A2
    printf("Cent sign: %x\n", codepoint_to_utf8(0x00A2));
    // https://codepoints.net/U+2603
    printf("Snowman: %x\n", codepoint_to_utf8(0x02603));
    // https://codepoints.net/U+10160
    printf("GREEK ACROPHONIC TROEZENIAN TEN: %x\n", codepoint_to_utf8(0x10160));

    printf("Out of range: %x\n", codepoint_to_utf8(0x00200000));

This is an interesting exercise, but if you want to do this for real use a pre-existing library. Gnome Lib has Unicode manipulation functions, and a lot more missing pieces of C.

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  • The initial test if (codepoint > 0x001FFFFF) is incorrect. It should be if (codepoint > 0x0010FFFF) and if type win_t is signed, an extra test for negative values is needed too. To make things worse, win_t can have as few as 15 value bits... such a mess. – chqrlie Feb 4 '17 at 15:47
  • @chqrlie Thanks, I fat fingered the UTF-32 check. As for wint_t, by my reading it must be large enough to hold all locales on the system, and assuming the system has UTF-8 seems reasonable (I thought about putting in an assert, but it's 2017); is that not true? It does drag in negatives. uint32_t might be better, but it makes returning an error code difficult. – Schwern Feb 4 '17 at 20:52

Many ways to do this fun exercise, converting a code point to UTF-8.

As not to give it all the coding experience away, following is a pseudo code to get OP started.

#define UTF_WIDTH1_MAX       0x7F
#define UTF_WIDTH2_MAX       0x7FF
#define UTF_WIDTH3_MAX       0xFFFF
#define UTF_WIDTH4_MAX       0x10FFFF

void PrintCodepointUTF8(uint32_t codepoint) {
  uint8_t first;
  uint8_t continuation_bytes[3];
  unsigned continuation_bytes_n;
  if (codepoint <= UTF_WIDTH1_MAX) {
    first = codepoint;
    continuation_bytes = 0;
  } else if (codepoint <= UTF_WIDTH2_MAX) {
    // extract 5 bits for first and 6 bits for one continuation_byte
    // and set some bits
    first = ...;
    continuation_bytes = ...
    continuation_bytes_n = 1;
  } else   if (codepoint <= UTF_WIDTH4_MAX) {
    if (isasurrogate(codepoint)) fail.
    // else extract 4 bits for first and 6 bits for each continuation_byte
    // and set some bits
    first = ...;
    continuation_bytes = ...
    continuation_bytes_n = 2;
  } else   if (codepoint <= UTF_WIDTH4_MAX) {
    // extract 3 bits for first and 6 bits for each continuation_byte
    // and set some bits
    first = ...;
    continuation_bytes = ...
    continuation_bytes_n = 3;
  } else {
    fail out of range.
  print first and 0-3 continuation_bytes
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  • I really hope printing in binary is a/the key point here, because otherwise I just basically handed OP their code on a platter (in my answer; didn't see yours while I was writing mine). Hate that; prefer to help learn, not skip work. – Nominal Animal Feb 2 '17 at 22:27
  • @NominalAnimal Hmmm, a positive different stroke for different folks. BTW: why decimal constant in code < 1114112U? Lots of Us too. Not needed, but not bad either. A surrogate test would be nice there too - now maybe thats too much for OP, maybe add next week. – chux - Reinstate Monica Feb 2 '17 at 22:57
  • Didn't notice it was decimal! :) Because I explicitly use an unsigned integer argument for the code point, I reject negative codepoints as too large (because they get converted to unsigned int according to C rules). The Us are there to raise the very question you posed; i.e. *"why are these constants explicitly unsigned?". I assume that those who blindly copy the code will just convert the unsigned ints to ints and drop the Us, which will make the code fail for negative codepoints. If I were testing others' code for this, I'd test a common bug: EOF or WEOF. – Nominal Animal Feb 3 '17 at 4:16

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