thodg/libgit2/deps/ntlmclient/utf8.h

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• Hash : a7f65f03
  Author :
  Date : 2019-03-21T15:42:57
  

  ntlm: add ntlmclient as a dependency Include https://github.com/ethomson/ntlmclient as a dependency.

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• deps/ntlmclient/utf8.h

• // The latest version of this library is available on GitHub;
  // https://github.com/sheredom/utf8.h
  
  // This is free and unencumbered software released into the public domain.
  //
  // Anyone is free to copy, modify, publish, use, compile, sell, or
  // distribute this software, either in source code form or as a compiled
  // binary, for any purpose, commercial or non-commercial, and by any
  // means.
  //
  // In jurisdictions that recognize copyright laws, the author or authors
  // of this software dedicate any and all copyright interest in the
  // software to the public domain. We make this dedication for the benefit
  // of the public at large and to the detriment of our heirs and
  // successors. We intend this dedication to be an overt act of
  // relinquishment in perpetuity of all present and future rights to this
  // software under copyright law.
  //
  // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
  // EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
  // MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
  // IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR
  // OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
  // ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
  // OTHER DEALINGS IN THE SOFTWARE.
  //
  // For more information, please refer to <http://unlicense.org/>
  
  #ifndef SHEREDOM_UTF8_H_INCLUDED
  #define SHEREDOM_UTF8_H_INCLUDED
  
  #if defined(_MSC_VER)
  #pragma warning(push)
  
  // disable 'bytes padding added after construct' warning
  #pragma warning(disable : 4820)
  #endif
  
  #include <stddef.h>
  #include <stdlib.h>
  
  #if defined(_MSC_VER)
  #pragma warning(pop)
  #endif
  
  #if defined(_MSC_VER)
  typedef __int32 utf8_int32_t;
  #else
  #include <stdint.h>
  typedef int32_t utf8_int32_t;
  #endif
  
  #if defined(__clang__)
  #pragma clang diagnostic push
  #pragma clang diagnostic ignored "-Wold-style-cast"
  #pragma clang diagnostic ignored "-Wcast-qual"
  #endif
  
  #ifdef __cplusplus
  extern "C" {
  #endif
  
  #if defined(__clang__) || defined(__GNUC__)
  #define utf8_nonnull __attribute__((nonnull))
  #define utf8_pure __attribute__((pure))
  #define utf8_restrict __restrict__
  #define utf8_weak __attribute__((weak))
  #elif defined(_MSC_VER)
  #define utf8_nonnull
  #define utf8_pure
  #define utf8_restrict __restrict
  #define utf8_weak __inline
  #else
  #error Non clang, non gcc, non MSVC compiler found!
  #endif
  
  #ifdef __cplusplus
  #define utf8_null NULL
  #else
  #define utf8_null 0
  #endif
  
  // Return less than 0, 0, greater than 0 if src1 < src2, src1 == src2, src1 >
  // src2 respectively, case insensitive.
  utf8_nonnull utf8_pure utf8_weak int utf8casecmp(const void *src1,
                                                   const void *src2);
  
  // Append the utf8 string src onto the utf8 string dst.
  utf8_nonnull utf8_weak void *utf8cat(void *utf8_restrict dst,
                                       const void *utf8_restrict src);
  
  // Find the first match of the utf8 codepoint chr in the utf8 string src.
  utf8_nonnull utf8_pure utf8_weak void *utf8chr(const void *src,
                                                 utf8_int32_t chr);
  
  // Return less than 0, 0, greater than 0 if src1 < src2,
  // src1 == src2, src1 > src2 respectively.
  utf8_nonnull utf8_pure utf8_weak int utf8cmp(const void *src1,
                                               const void *src2);
  
  // Copy the utf8 string src onto the memory allocated in dst.
  utf8_nonnull utf8_weak void *utf8cpy(void *utf8_restrict dst,
                                       const void *utf8_restrict src);
  
  // Number of utf8 codepoints in the utf8 string src that consists entirely
  // of utf8 codepoints not from the utf8 string reject.
  utf8_nonnull utf8_pure utf8_weak size_t utf8cspn(const void *src,
                                                   const void *reject);
  
  // Duplicate the utf8 string src by getting its size, malloc'ing a new buffer
  // copying over the data, and returning that. Or 0 if malloc failed.
  utf8_nonnull utf8_weak void *utf8dup(const void *src);
  
  // Number of utf8 codepoints in the utf8 string str,
  // excluding the null terminating byte.
  utf8_nonnull utf8_pure utf8_weak size_t utf8len(const void *str);
  
  // Return less than 0, 0, greater than 0 if src1 < src2, src1 == src2, src1 >
  // src2 respectively, case insensitive. Checking at most n bytes of each utf8
  // string.
  utf8_nonnull utf8_pure utf8_weak int utf8ncasecmp(const void *src1,
                                                    const void *src2, size_t n);
  
  // Append the utf8 string src onto the utf8 string dst,
  // writing at most n+1 bytes. Can produce an invalid utf8
  // string if n falls partway through a utf8 codepoint.
  utf8_nonnull utf8_weak void *utf8ncat(void *utf8_restrict dst,
                                        const void *utf8_restrict src, size_t n);
  
  // Return less than 0, 0, greater than 0 if src1 < src2,
  // src1 == src2, src1 > src2 respectively. Checking at most n
  // bytes of each utf8 string.
  utf8_nonnull utf8_pure utf8_weak int utf8ncmp(const void *src1,
                                                const void *src2, size_t n);
  
  // Copy the utf8 string src onto the memory allocated in dst.
  // Copies at most n bytes. If there is no terminating null byte in
  // the first n bytes of src, the string placed into dst will not be
  // null-terminated. If the size (in bytes) of src is less than n,
  // extra null terminating bytes are appended to dst such that at
  // total of n bytes are written. Can produce an invalid utf8
  // string if n falls partway through a utf8 codepoint.
  utf8_nonnull utf8_weak void *utf8ncpy(void *utf8_restrict dst,
                                        const void *utf8_restrict src, size_t n);
  
  // Similar to utf8dup, except that at most n bytes of src are copied. If src is
  // longer than n, only n bytes are copied and a null byte is added.
  //
  // Returns a new string if successful, 0 otherwise
  utf8_nonnull utf8_weak void *utf8ndup(const void *src, size_t n);
  
  // Locates the first occurence in the utf8 string str of any byte in the
  // utf8 string accept, or 0 if no match was found.
  utf8_nonnull utf8_pure utf8_weak void *utf8pbrk(const void *str,
                                                  const void *accept);
  
  // Find the last match of the utf8 codepoint chr in the utf8 string src.
  utf8_nonnull utf8_pure utf8_weak void *utf8rchr(const void *src, int chr);
  
  // Number of bytes in the utf8 string str,
  // including the null terminating byte.
  utf8_nonnull utf8_pure utf8_weak size_t utf8size(const void *str);
  
  // Number of utf8 codepoints in the utf8 string src that consists entirely
  // of utf8 codepoints from the utf8 string accept.
  utf8_nonnull utf8_pure utf8_weak size_t utf8spn(const void *src,
                                                  const void *accept);
  
  // The position of the utf8 string needle in the utf8 string haystack.
  utf8_nonnull utf8_pure utf8_weak void *utf8str(const void *haystack,
                                                 const void *needle);
  
  // The position of the utf8 string needle in the utf8 string haystack, case
  // insensitive.
  utf8_nonnull utf8_pure utf8_weak void *utf8casestr(const void *haystack,
                                                     const void *needle);
  
  // Return 0 on success, or the position of the invalid
  // utf8 codepoint on failure.
  utf8_nonnull utf8_pure utf8_weak void *utf8valid(const void *str);
  
  // Sets out_codepoint to the next utf8 codepoint in str, and returns the address
  // of the utf8 codepoint after the current one in str.
  utf8_nonnull utf8_weak void *
  utf8codepoint(const void *utf8_restrict str,
                utf8_int32_t *utf8_restrict out_codepoint);
  
  // Returns the size of the given codepoint in bytes.
  utf8_weak size_t utf8codepointsize(utf8_int32_t chr);
  
  // Write a codepoint to the given string, and return the address to the next
  // place after the written codepoint. Pass how many bytes left in the buffer to
  // n. If there is not enough space for the codepoint, this function returns
  // null.
  utf8_nonnull utf8_weak void *utf8catcodepoint(void *utf8_restrict str,
                                                utf8_int32_t chr, size_t n);
  
  // Returns 1 if the given character is lowercase, or 0 if it is not.
  utf8_weak int utf8islower(utf8_int32_t chr);
  
  // Returns 1 if the given character is uppercase, or 0 if it is not.
  utf8_weak int utf8isupper(utf8_int32_t chr);
  
  // Transform the given string into all lowercase codepoints.
  utf8_nonnull utf8_weak void utf8lwr(void *utf8_restrict str);
  
  // Transform the given string into all uppercase codepoints.
  utf8_nonnull utf8_weak void utf8upr(void *utf8_restrict str);
  
  // Make a codepoint lower case if possible.
  utf8_weak utf8_int32_t utf8lwrcodepoint(utf8_int32_t cp);
  
  // Make a codepoint upper case if possible.
  utf8_weak utf8_int32_t utf8uprcodepoint(utf8_int32_t cp);
  
  #undef utf8_weak
  #undef utf8_pure
  #undef utf8_nonnull
  
  int utf8casecmp(const void *src1, const void *src2) {
    utf8_int32_t src1_cp, src2_cp, src1_orig_cp, src2_orig_cp;
  
    for (;;) {
      src1 = utf8codepoint(src1, &src1_cp);
      src2 = utf8codepoint(src2, &src2_cp);
  
      // Take a copy of src1 & src2
      src1_orig_cp = src1_cp;
      src2_orig_cp = src2_cp;
  
      // Lower the srcs if required
      src1_cp = utf8lwrcodepoint(src1_cp);
      src2_cp = utf8lwrcodepoint(src2_cp);
  
      // Check if the lowered codepoints match
      if ((0 == src1_orig_cp) && (0 == src2_orig_cp)) {
        return 0;
      } else if (src1_cp == src2_cp) {
        continue;
      }
  
      // If they don't match, then we return which of the original's are less
      if (src1_orig_cp < src2_orig_cp) {
        return -1;
      } else if (src1_orig_cp > src2_orig_cp) {
        return 1;
      }
    }
  }
  
  void *utf8cat(void *utf8_restrict dst, const void *utf8_restrict src) {
    char *d = (char *)dst;
    const char *s = (const char *)src;
  
    // find the null terminating byte in dst
    while ('\0' != *d) {
      d++;
    }
  
    // overwriting the null terminating byte in dst, append src byte-by-byte
    while ('\0' != *s) {
      *d++ = *s++;
    }
  
    // write out a new null terminating byte into dst
    *d = '\0';
  
    return dst;
  }
  
  void *utf8chr(const void *src, utf8_int32_t chr) {
    char c[5] = {'\0', '\0', '\0', '\0', '\0'};
  
    if (0 == chr) {
      // being asked to return position of null terminating byte, so
      // just run s to the end, and return!
      const char *s = (const char *)src;
      while ('\0' != *s) {
        s++;
      }
      return (void *)s;
    } else if (0 == ((utf8_int32_t)0xffffff80 & chr)) {
      // 1-byte/7-bit ascii
      // (0b0xxxxxxx)
      c[0] = (char)chr;
    } else if (0 == ((utf8_int32_t)0xfffff800 & chr)) {
      // 2-byte/11-bit utf8 code point
      // (0b110xxxxx 0b10xxxxxx)
      c[0] = 0xc0 | (char)(chr >> 6);
      c[1] = 0x80 | (char)(chr & 0x3f);
    } else if (0 == ((utf8_int32_t)0xffff0000 & chr)) {
      // 3-byte/16-bit utf8 code point
      // (0b1110xxxx 0b10xxxxxx 0b10xxxxxx)
      c[0] = 0xe0 | (char)(chr >> 12);
      c[1] = 0x80 | (char)((chr >> 6) & 0x3f);
      c[2] = 0x80 | (char)(chr & 0x3f);
    } else { // if (0 == ((int)0xffe00000 & chr)) {
      // 4-byte/21-bit utf8 code point
      // (0b11110xxx 0b10xxxxxx 0b10xxxxxx 0b10xxxxxx)
      c[0] = 0xf0 | (char)(chr >> 18);
      c[1] = 0x80 | (char)((chr >> 12) & 0x3f);
      c[2] = 0x80 | (char)((chr >> 6) & 0x3f);
      c[3] = 0x80 | (char)(chr & 0x3f);
    }
  
    // we've made c into a 2 utf8 codepoint string, one for the chr we are
    // seeking, another for the null terminating byte. Now use utf8str to
    // search
    return utf8str(src, c);
  }
  
  int utf8cmp(const void *src1, const void *src2) {
    const unsigned char *s1 = (const unsigned char *)src1;
    const unsigned char *s2 = (const unsigned char *)src2;
  
    while (('\0' != *s1) || ('\0' != *s2)) {
      if (*s1 < *s2) {
        return -1;
      } else if (*s1 > *s2) {
        return 1;
      }
  
      s1++;
      s2++;
    }
  
    // both utf8 strings matched
    return 0;
  }
  
  int utf8coll(const void *src1, const void *src2);
  
  void *utf8cpy(void *utf8_restrict dst, const void *utf8_restrict src) {
    char *d = (char *)dst;
    const char *s = (const char *)src;
  
    // overwriting anything previously in dst, write byte-by-byte
    // from src
    while ('\0' != *s) {
      *d++ = *s++;
    }
  
    // append null terminating byte
    *d = '\0';
  
    return dst;
  }
  
  size_t utf8cspn(const void *src, const void *reject) {
    const char *s = (const char *)src;
    size_t chars = 0;
  
    while ('\0' != *s) {
      const char *r = (const char *)reject;
      size_t offset = 0;
  
      while ('\0' != *r) {
        // checking that if *r is the start of a utf8 codepoint
        // (it is not 0b10xxxxxx) and we have successfully matched
        // a previous character (0 < offset) - we found a match
        if ((0x80 != (0xc0 & *r)) && (0 < offset)) {
          return chars;
        } else {
          if (*r == s[offset]) {
            // part of a utf8 codepoint matched, so move our checking
            // onwards to the next byte
            offset++;
            r++;
          } else {
            // r could be in the middle of an unmatching utf8 code point,
            // so we need to march it on to the next character beginning,
  
            do {
              r++;
            } while (0x80 == (0xc0 & *r));
  
            // reset offset too as we found a mismatch
            offset = 0;
          }
        }
      }
  
      // the current utf8 codepoint in src did not match reject, but src
      // could have been partway through a utf8 codepoint, so we need to
      // march it onto the next utf8 codepoint starting byte
      do {
        s++;
      } while ((0x80 == (0xc0 & *s)));
      chars++;
    }
  
    return chars;
  }
  
  size_t utf8size(const void *str);
  
  void *utf8dup(const void *src) {
    const char *s = (const char *)src;
    char *n = utf8_null;
  
    // figure out how many bytes (including the terminator) we need to copy first
    size_t bytes = utf8size(src);
  
    n = (char *)malloc(bytes);
  
    if (utf8_null == n) {
      // out of memory so we bail
      return utf8_null;
    } else {
      bytes = 0;
  
      // copy src byte-by-byte into our new utf8 string
      while ('\0' != s[bytes]) {
        n[bytes] = s[bytes];
        bytes++;
      }
  
      // append null terminating byte
      n[bytes] = '\0';
      return n;
    }
  }
  
  void *utf8fry(const void *str);
  
  size_t utf8len(const void *str) {
    const unsigned char *s = (const unsigned char *)str;
    size_t length = 0;
  
    while ('\0' != *s) {
      if (0xf0 == (0xf8 & *s)) {
        // 4-byte utf8 code point (began with 0b11110xxx)
        s += 4;
      } else if (0xe0 == (0xf0 & *s)) {
        // 3-byte utf8 code point (began with 0b1110xxxx)
        s += 3;
      } else if (0xc0 == (0xe0 & *s)) {
        // 2-byte utf8 code point (began with 0b110xxxxx)
        s += 2;
      } else { // if (0x00 == (0x80 & *s)) {
        // 1-byte ascii (began with 0b0xxxxxxx)
        s += 1;
      }
  
      // no matter the bytes we marched s forward by, it was
      // only 1 utf8 codepoint
      length++;
    }
  
    return length;
  }
  
  int utf8ncasecmp(const void *src1, const void *src2, size_t n) {
    utf8_int32_t src1_cp, src2_cp, src1_orig_cp, src2_orig_cp;
  
    do {
      const unsigned char *const s1 = (const unsigned char *)src1;
      const unsigned char *const s2 = (const unsigned char *)src2;
  
      // first check that we have enough bytes left in n to contain an entire
      // codepoint
      if (0 == n) {
        return 0;
      }
  
      if ((1 == n) && ((0xc0 == (0xe0 & *s1)) || (0xc0 == (0xe0 & *s2)))) {
        const utf8_int32_t c1 = (0xe0 & *s1);
        const utf8_int32_t c2 = (0xe0 & *s2);
  
        if (c1 < c2) {
          return -1;
        } else if (c1 > c2) {
          return 1;
        } else {
          return 0;
        }
      }
  
      if ((2 >= n) && ((0xe0 == (0xf0 & *s1)) || (0xe0 == (0xf0 & *s2)))) {
        const utf8_int32_t c1 = (0xf0 & *s1);
        const utf8_int32_t c2 = (0xf0 & *s2);
  
        if (c1 < c2) {
          return -1;
        } else if (c1 > c2) {
          return 1;
        } else {
          return 0;
        }
      }
  
      if ((3 >= n) && ((0xf0 == (0xf8 & *s1)) || (0xf0 == (0xf8 & *s2)))) {
        const utf8_int32_t c1 = (0xf8 & *s1);
        const utf8_int32_t c2 = (0xf8 & *s2);
  
        if (c1 < c2) {
          return -1;
        } else if (c1 > c2) {
          return 1;
        } else {
          return 0;
        }
      }
  
      src1 = utf8codepoint(src1, &src1_cp);
      src2 = utf8codepoint(src2, &src2_cp);
      n -= utf8codepointsize(src1_cp);
  
      // Take a copy of src1 & src2
      src1_orig_cp = src1_cp;
      src2_orig_cp = src2_cp;
  
      // Lower srcs if required
      src1_cp = utf8lwrcodepoint(src1_cp);
      src2_cp = utf8lwrcodepoint(src2_cp);
  
      // Check if the lowered codepoints match
      if ((0 == src1_orig_cp) && (0 == src2_orig_cp)) {
        return 0;
      } else if (src1_cp == src2_cp) {
        continue;
      }
  
      // If they don't match, then we return which of the original's are less
      if (src1_orig_cp < src2_orig_cp) {
        return -1;
      } else if (src1_orig_cp > src2_orig_cp) {
        return 1;
      }
    } while (0 < n);
  
    // both utf8 strings matched
    return 0;
  }
  
  void *utf8ncat(void *utf8_restrict dst, const void *utf8_restrict src,
                 size_t n) {
    char *d = (char *)dst;
    const char *s = (const char *)src;
  
    // find the null terminating byte in dst
    while ('\0' != *d) {
      d++;
    }
  
    // overwriting the null terminating byte in dst, append src byte-by-byte
    // stopping if we run out of space
    do {
      *d++ = *s++;
    } while (('\0' != *s) && (0 != --n));
  
    // write out a new null terminating byte into dst
    *d = '\0';
  
    return dst;
  }
  
  int utf8ncmp(const void *src1, const void *src2, size_t n) {
    const unsigned char *s1 = (const unsigned char *)src1;
    const unsigned char *s2 = (const unsigned char *)src2;
  
    while ((('\0' != *s1) || ('\0' != *s2)) && (0 != n--)) {
      if (*s1 < *s2) {
        return -1;
      } else if (*s1 > *s2) {
        return 1;
      }
  
      s1++;
      s2++;
    }
  
    // both utf8 strings matched
    return 0;
  }
  
  void *utf8ncpy(void *utf8_restrict dst, const void *utf8_restrict src,
                 size_t n) {
    char *d = (char *)dst;
    const char *s = (const char *)src;
  
    // overwriting anything previously in dst, write byte-by-byte
    // from src
    do {
      *d++ = *s++;
    } while (('\0' != *s) && (0 != --n));
  
    // append null terminating byte
    while (0 != n) {
      *d++ = '\0';
      n--;
    }
  
    return dst;
  }
  
  void *utf8ndup(const void *src, size_t n) {
    const char *s = (const char *)src;
    char *c = utf8_null;
    size_t bytes = 0;
  
    // Find the end of the string or stop when n is reached
    while ('\0' != s[bytes] && bytes < n) {
      bytes++;
    }
  
    // In case bytes is actually less than n, we need to set it
    // to be used later in the copy byte by byte.
    n = bytes;
  
    c = (char *)malloc(bytes + 1);
    if (utf8_null == c) {
      // out of memory so we bail
      return utf8_null;
    }
  
    bytes = 0;
  
    // copy src byte-by-byte into our new utf8 string
    while ('\0' != s[bytes] && bytes < n) {
      c[bytes] = s[bytes];
      bytes++;
    }
  
    // append null terminating byte
    c[bytes] = '\0';
    return c;
  }
  
  void *utf8rchr(const void *src, int chr) {
    const char *s = (const char *)src;
    const char *match = utf8_null;
    char c[5] = {'\0', '\0', '\0', '\0', '\0'};
  
    if (0 == chr) {
      // being asked to return position of null terminating byte, so
      // just run s to the end, and return!
      while ('\0' != *s) {
        s++;
      }
      return (void *)s;
    } else if (0 == ((int)0xffffff80 & chr)) {
      // 1-byte/7-bit ascii
      // (0b0xxxxxxx)
      c[0] = (char)chr;
    } else if (0 == ((int)0xfffff800 & chr)) {
      // 2-byte/11-bit utf8 code point
      // (0b110xxxxx 0b10xxxxxx)
      c[0] = 0xc0 | (char)(chr >> 6);
      c[1] = 0x80 | (char)(chr & 0x3f);
    } else if (0 == ((int)0xffff0000 & chr)) {
      // 3-byte/16-bit utf8 code point
      // (0b1110xxxx 0b10xxxxxx 0b10xxxxxx)
      c[0] = 0xe0 | (char)(chr >> 12);
      c[1] = 0x80 | (char)((chr >> 6) & 0x3f);
      c[2] = 0x80 | (char)(chr & 0x3f);
    } else { // if (0 == ((int)0xffe00000 & chr)) {
      // 4-byte/21-bit utf8 code point
      // (0b11110xxx 0b10xxxxxx 0b10xxxxxx 0b10xxxxxx)
      c[0] = 0xf0 | (char)(chr >> 18);
      c[1] = 0x80 | (char)((chr >> 12) & 0x3f);
      c[2] = 0x80 | (char)((chr >> 6) & 0x3f);
      c[3] = 0x80 | (char)(chr & 0x3f);
    }
  
    // we've created a 2 utf8 codepoint string in c that is
    // the utf8 character asked for by chr, and a null
    // terminating byte
  
    while ('\0' != *s) {
      size_t offset = 0;
  
      while (s[offset] == c[offset]) {
        offset++;
      }
  
      if ('\0' == c[offset]) {
        // we found a matching utf8 code point
        match = s;
        s += offset;
      } else {
        s += offset;
  
        // need to march s along to next utf8 codepoint start
        // (the next byte that doesn't match 0b10xxxxxx)
        if ('\0' != *s) {
          do {
            s++;
          } while (0x80 == (0xc0 & *s));
        }
      }
    }
  
    // return the last match we found (or 0 if no match was found)
    return (void *)match;
  }
  
  void *utf8pbrk(const void *str, const void *accept) {
    const char *s = (const char *)str;
  
    while ('\0' != *s) {
      const char *a = (const char *)accept;
      size_t offset = 0;
  
      while ('\0' != *a) {
        // checking that if *a is the start of a utf8 codepoint
        // (it is not 0b10xxxxxx) and we have successfully matched
        // a previous character (0 < offset) - we found a match
        if ((0x80 != (0xc0 & *a)) && (0 < offset)) {
          return (void *)s;
        } else {
          if (*a == s[offset]) {
            // part of a utf8 codepoint matched, so move our checking
            // onwards to the next byte
            offset++;
            a++;
          } else {
            // r could be in the middle of an unmatching utf8 code point,
            // so we need to march it on to the next character beginning,
  
            do {
              a++;
            } while (0x80 == (0xc0 & *a));
  
            // reset offset too as we found a mismatch
            offset = 0;
          }
        }
      }
  
      // we found a match on the last utf8 codepoint
      if (0 < offset) {
        return (void *)s;
      }
  
      // the current utf8 codepoint in src did not match accept, but src
      // could have been partway through a utf8 codepoint, so we need to
      // march it onto the next utf8 codepoint starting byte
      do {
        s++;
      } while ((0x80 == (0xc0 & *s)));
    }
  
    return utf8_null;
  }
  
  size_t utf8size(const void *str) {
    const char *s = (const char *)str;
    size_t size = 0;
    while ('\0' != s[size]) {
      size++;
    }
  
    // we are including the null terminating byte in the size calculation
    size++;
    return size;
  }
  
  size_t utf8spn(const void *src, const void *accept) {
    const char *s = (const char *)src;
    size_t chars = 0;
  
    while ('\0' != *s) {
      const char *a = (const char *)accept;
      size_t offset = 0;
  
      while ('\0' != *a) {
        // checking that if *r is the start of a utf8 codepoint
        // (it is not 0b10xxxxxx) and we have successfully matched
        // a previous character (0 < offset) - we found a match
        if ((0x80 != (0xc0 & *a)) && (0 < offset)) {
          // found a match, so increment the number of utf8 codepoints
          // that have matched and stop checking whether any other utf8
          // codepoints in a match
          chars++;
          s += offset;
          break;
        } else {
          if (*a == s[offset]) {
            offset++;
            a++;
          } else {
            // a could be in the middle of an unmatching utf8 codepoint,
            // so we need to march it on to the next character beginning,
            do {
              a++;
            } while (0x80 == (0xc0 & *a));
  
            // reset offset too as we found a mismatch
            offset = 0;
          }
        }
      }
  
      // if a got to its terminating null byte, then we didn't find a match.
      // Return the current number of matched utf8 codepoints
      if ('\0' == *a) {
        return chars;
      }
    }
  
    return chars;
  }
  
  void *utf8str(const void *haystack, const void *needle) {
    const char *h = (const char *)haystack;
  
    // if needle has no utf8 codepoints before the null terminating
    // byte then return haystack
    if ('\0' == *((const char *)needle)) {
      return (void *)haystack;
    }
  
    while ('\0' != *h) {
      const char *maybeMatch = h;
      const char *n = (const char *)needle;
  
      while (*h == *n && (*h != '\0' && *n != '\0')) {
        n++;
        h++;
      }
  
      if ('\0' == *n) {
        // we found the whole utf8 string for needle in haystack at
        // maybeMatch, so return it
        return (void *)maybeMatch;
      } else {
        // h could be in the middle of an unmatching utf8 codepoint,
        // so we need to march it on to the next character beginning,
        if ('\0' != *h) {
          do {
            h++;
          } while (0x80 == (0xc0 & *h));
        }
      }
    }
  
    // no match
    return utf8_null;
  }
  
  void *utf8casestr(const void *haystack, const void *needle) {
    const void *h = haystack;
  
    // if needle has no utf8 codepoints before the null terminating
    // byte then return haystack
    if ('\0' == *((const char *)needle)) {
      return (void *)haystack;
    }
  
    for (;;) {
      const void *maybeMatch = h;
      const void *n = needle;
      utf8_int32_t h_cp, n_cp;
  
      h = utf8codepoint(h, &h_cp);
      n = utf8codepoint(n, &n_cp);
  
      while ((0 != h_cp) && (0 != n_cp)) {
        h_cp = utf8lwrcodepoint(h_cp);
        n_cp = utf8lwrcodepoint(n_cp);
  
        // if we find a mismatch, bail out!
        if (h_cp != n_cp) {
          break;
        }
  
        h = utf8codepoint(h, &h_cp);
        n = utf8codepoint(n, &n_cp);
      }
  
      if (0 == n_cp) {
        // we found the whole utf8 string for needle in haystack at
        // maybeMatch, so return it
        return (void *)maybeMatch;
      }
  
      if (0 == h_cp) {
        // no match
        return utf8_null;
      }
    }
  }
  
  void *utf8valid(const void *str) {
    const char *s = (const char *)str;
  
    while ('\0' != *s) {
      if (0xf0 == (0xf8 & *s)) {
        // ensure each of the 3 following bytes in this 4-byte
        // utf8 codepoint began with 0b10xxxxxx
        if ((0x80 != (0xc0 & s[1])) || (0x80 != (0xc0 & s[2])) ||
            (0x80 != (0xc0 & s[3]))) {
          return (void *)s;
        }
  
        // ensure that our utf8 codepoint ended after 4 bytes
        if (0x80 == (0xc0 & s[4])) {
          return (void *)s;
        }
  
        // ensure that the top 5 bits of this 4-byte utf8
        // codepoint were not 0, as then we could have used
        // one of the smaller encodings
        if ((0 == (0x07 & s[0])) && (0 == (0x30 & s[1]))) {
          return (void *)s;
        }
  
        // 4-byte utf8 code point (began with 0b11110xxx)
        s += 4;
      } else if (0xe0 == (0xf0 & *s)) {
        // ensure each of the 2 following bytes in this 3-byte
        // utf8 codepoint began with 0b10xxxxxx
        if ((0x80 != (0xc0 & s[1])) || (0x80 != (0xc0 & s[2]))) {
          return (void *)s;
        }
  
        // ensure that our utf8 codepoint ended after 3 bytes
        if (0x80 == (0xc0 & s[3])) {
          return (void *)s;
        }
  
        // ensure that the top 5 bits of this 3-byte utf8
        // codepoint were not 0, as then we could have used
        // one of the smaller encodings
        if ((0 == (0x0f & s[0])) && (0 == (0x20 & s[1]))) {
          return (void *)s;
        }
  
        // 3-byte utf8 code point (began with 0b1110xxxx)
        s += 3;
      } else if (0xc0 == (0xe0 & *s)) {
        // ensure the 1 following byte in this 2-byte
        // utf8 codepoint began with 0b10xxxxxx
        if (0x80 != (0xc0 & s[1])) {
          return (void *)s;
        }
  
        // ensure that our utf8 codepoint ended after 2 bytes
        if (0x80 == (0xc0 & s[2])) {
          return (void *)s;
        }
  
        // ensure that the top 4 bits of this 2-byte utf8
        // codepoint were not 0, as then we could have used
        // one of the smaller encodings
        if (0 == (0x1e & s[0])) {
          return (void *)s;
        }
  
        // 2-byte utf8 code point (began with 0b110xxxxx)
        s += 2;
      } else if (0x00 == (0x80 & *s)) {
        // 1-byte ascii (began with 0b0xxxxxxx)
        s += 1;
      } else {
        // we have an invalid 0b1xxxxxxx utf8 code point entry
        return (void *)s;
      }
    }
  
    return utf8_null;
  }
  
  void *utf8codepoint(const void *utf8_restrict str,
                      utf8_int32_t *utf8_restrict out_codepoint) {
    const char *s = (const char *)str;
  
    if (0xf0 == (0xf8 & s[0])) {
      // 4 byte utf8 codepoint
      *out_codepoint = ((0x07 & s[0]) << 18) | ((0x3f & s[1]) << 12) |
                       ((0x3f & s[2]) << 6) | (0x3f & s[3]);
      s += 4;
    } else if (0xe0 == (0xf0 & s[0])) {
      // 3 byte utf8 codepoint
      *out_codepoint =
          ((0x0f & s[0]) << 12) | ((0x3f & s[1]) << 6) | (0x3f & s[2]);
      s += 3;
    } else if (0xc0 == (0xe0 & s[0])) {
      // 2 byte utf8 codepoint
      *out_codepoint = ((0x1f & s[0]) << 6) | (0x3f & s[1]);
      s += 2;
    } else {
      // 1 byte utf8 codepoint otherwise
      *out_codepoint = s[0];
      s += 1;
    }
  
    return (void *)s;
  }
  
  size_t utf8codepointsize(utf8_int32_t chr) {
    if (0 == ((utf8_int32_t)0xffffff80 & chr)) {
      return 1;
    } else if (0 == ((utf8_int32_t)0xfffff800 & chr)) {
      return 2;
    } else if (0 == ((utf8_int32_t)0xffff0000 & chr)) {
      return 3;
    } else { // if (0 == ((int)0xffe00000 & chr)) {
      return 4;
    }
  }
  
  void *utf8catcodepoint(void *utf8_restrict str, utf8_int32_t chr, size_t n) {
    char *s = (char *)str;
  
    if (0 == ((utf8_int32_t)0xffffff80 & chr)) {
      // 1-byte/7-bit ascii
      // (0b0xxxxxxx)
      if (n < 1) {
        return utf8_null;
      }
      s[0] = (char)chr;
      s += 1;
    } else if (0 == ((utf8_int32_t)0xfffff800 & chr)) {
      // 2-byte/11-bit utf8 code point
      // (0b110xxxxx 0b10xxxxxx)
      if (n < 2) {
        return utf8_null;
      }
      s[0] = 0xc0 | (char)(chr >> 6);
      s[1] = 0x80 | (char)(chr & 0x3f);
      s += 2;
    } else if (0 == ((utf8_int32_t)0xffff0000 & chr)) {
      // 3-byte/16-bit utf8 code point
      // (0b1110xxxx 0b10xxxxxx 0b10xxxxxx)
      if (n < 3) {
        return utf8_null;
      }
      s[0] = 0xe0 | (char)(chr >> 12);
      s[1] = 0x80 | (char)((chr >> 6) & 0x3f);
      s[2] = 0x80 | (char)(chr & 0x3f);
      s += 3;
    } else { // if (0 == ((int)0xffe00000 & chr)) {
      // 4-byte/21-bit utf8 code point
      // (0b11110xxx 0b10xxxxxx 0b10xxxxxx 0b10xxxxxx)
      if (n < 4) {
        return utf8_null;
      }
      s[0] = 0xf0 | (char)(chr >> 18);
      s[1] = 0x80 | (char)((chr >> 12) & 0x3f);
      s[2] = 0x80 | (char)((chr >> 6) & 0x3f);
      s[3] = 0x80 | (char)(chr & 0x3f);
      s += 4;
    }
  
    return s;
  }
  
  int utf8islower(utf8_int32_t chr) { return chr != utf8uprcodepoint(chr); }
  
  int utf8isupper(utf8_int32_t chr) { return chr != utf8lwrcodepoint(chr); }
  
  void utf8lwr(void *utf8_restrict str) {
    void *p, *pn;
    utf8_int32_t cp;
  
    p = (char *)str;
    pn = utf8codepoint(p, &cp);
  
    while (cp != 0) {
      const utf8_int32_t lwr_cp = utf8lwrcodepoint(cp);
      const size_t size = utf8codepointsize(lwr_cp);
  
      if (lwr_cp != cp) {
        utf8catcodepoint(p, lwr_cp, size);
      }
  
      p = pn;
      pn = utf8codepoint(p, &cp);
    }
  }
  
  void utf8upr(void *utf8_restrict str) {
    void *p, *pn;
    utf8_int32_t cp;
  
    p = (char *)str;
    pn = utf8codepoint(p, &cp);
  
    while (cp != 0) {
      const utf8_int32_t lwr_cp = utf8uprcodepoint(cp);
      const size_t size = utf8codepointsize(lwr_cp);
  
      if (lwr_cp != cp) {
        utf8catcodepoint(p, lwr_cp, size);
      }
  
      p = pn;
      pn = utf8codepoint(p, &cp);
    }
  }
  
  utf8_int32_t utf8lwrcodepoint(utf8_int32_t cp) {
    if (((0x0041 <= cp) && (0x005a >= cp)) ||
        ((0x00c0 <= cp) && (0x00d6 >= cp)) ||
        ((0x00d8 <= cp) && (0x00de >= cp)) ||
        ((0x0391 <= cp) && (0x03a1 >= cp)) ||
        ((0x03a3 <= cp) && (0x03ab >= cp))) {
      cp += 32;
    } else if (((0x0100 <= cp) && (0x012f >= cp)) ||
               ((0x0132 <= cp) && (0x0137 >= cp)) ||
               ((0x014a <= cp) && (0x0177 >= cp)) ||
               ((0x0182 <= cp) && (0x0185 >= cp)) ||
               ((0x01a0 <= cp) && (0x01a5 >= cp)) ||
               ((0x01de <= cp) && (0x01ef >= cp)) ||
               ((0x01f8 <= cp) && (0x021f >= cp)) ||
               ((0x0222 <= cp) && (0x0233 >= cp)) ||
               ((0x0246 <= cp) && (0x024f >= cp)) ||
               ((0x03d8 <= cp) && (0x03ef >= cp))) {
      cp |= 0x1;
    } else if (((0x0139 <= cp) && (0x0148 >= cp)) ||
               ((0x0179 <= cp) && (0x017e >= cp)) ||
               ((0x01af <= cp) && (0x01b0 >= cp)) ||
               ((0x01b3 <= cp) && (0x01b6 >= cp)) ||
               ((0x01cd <= cp) && (0x01dc >= cp))) {
      cp += 1;
      cp &= ~0x1;
    } else {
      switch (cp) {
      default: break;
      case 0x0178: cp = 0x00ff; break;
      case 0x0243: cp = 0x0180; break;
      case 0x018e: cp = 0x01dd; break;
      case 0x023d: cp = 0x019a; break;
      case 0x0220: cp = 0x019e; break;
      case 0x01b7: cp = 0x0292; break;
      case 0x01c4: cp = 0x01c6; break;
      case 0x01c7: cp = 0x01c9; break;
      case 0x01ca: cp = 0x01cc; break;
      case 0x01f1: cp = 0x01f3; break;
      case 0x01f7: cp = 0x01bf; break;
      case 0x0187: cp = 0x0188; break;
      case 0x018b: cp = 0x018c; break;
      case 0x0191: cp = 0x0192; break;
      case 0x0198: cp = 0x0199; break;
      case 0x01a7: cp = 0x01a8; break;
      case 0x01ac: cp = 0x01ad; break;
      case 0x01af: cp = 0x01b0; break;
      case 0x01b8: cp = 0x01b9; break;
      case 0x01bc: cp = 0x01bd; break;
      case 0x01f4: cp = 0x01f5; break;
      case 0x023b: cp = 0x023c; break;
      case 0x0241: cp = 0x0242; break;
      case 0x03fd: cp = 0x037b; break;
      case 0x03fe: cp = 0x037c; break;
      case 0x03ff: cp = 0x037d; break;
      case 0x037f: cp = 0x03f3; break;
      case 0x0386: cp = 0x03ac; break;
      case 0x0388: cp = 0x03ad; break;
      case 0x0389: cp = 0x03ae; break;
      case 0x038a: cp = 0x03af; break;
      case 0x038c: cp = 0x03cc; break;
      case 0x038e: cp = 0x03cd; break;
      case 0x038f: cp = 0x03ce; break;
      case 0x0370: cp = 0x0371; break;
      case 0x0372: cp = 0x0373; break;
      case 0x0376: cp = 0x0377; break;
      case 0x03f4: cp = 0x03d1; break;
      case 0x03cf: cp = 0x03d7; break;
      case 0x03f9: cp = 0x03f2; break;
      case 0x03f7: cp = 0x03f8; break;
      case 0x03fa: cp = 0x03fb; break;
      };
    }
  
    return cp;
  }
  
  utf8_int32_t utf8uprcodepoint(utf8_int32_t cp) {
    if (((0x0061 <= cp) && (0x007a >= cp)) ||
        ((0x00e0 <= cp) && (0x00f6 >= cp)) ||
        ((0x00f8 <= cp) && (0x00fe >= cp)) ||
        ((0x03b1 <= cp) && (0x03c1 >= cp)) ||
        ((0x03c3 <= cp) && (0x03cb >= cp))) {
      cp -= 32;
    } else if (((0x0100 <= cp) && (0x012f >= cp)) ||
               ((0x0132 <= cp) && (0x0137 >= cp)) ||
               ((0x014a <= cp) && (0x0177 >= cp)) ||
               ((0x0182 <= cp) && (0x0185 >= cp)) ||
               ((0x01a0 <= cp) && (0x01a5 >= cp)) ||
               ((0x01de <= cp) && (0x01ef >= cp)) ||
               ((0x01f8 <= cp) && (0x021f >= cp)) ||
               ((0x0222 <= cp) && (0x0233 >= cp)) ||
               ((0x0246 <= cp) && (0x024f >= cp)) ||
               ((0x03d8 <= cp) && (0x03ef >= cp))) {
      cp &= ~0x1;
    } else if (((0x0139 <= cp) && (0x0148 >= cp)) ||
               ((0x0179 <= cp) && (0x017e >= cp)) ||
               ((0x01af <= cp) && (0x01b0 >= cp)) ||
               ((0x01b3 <= cp) && (0x01b6 >= cp)) ||
               ((0x01cd <= cp) && (0x01dc >= cp))) {
      cp -= 1;
      cp |= 0x1;
    } else {
      switch (cp) {
      default: break;
      case 0x00ff: cp = 0x0178; break;
      case 0x0180: cp = 0x0243; break;
      case 0x01dd: cp = 0x018e; break;
      case 0x019a: cp = 0x023d; break;
      case 0x019e: cp = 0x0220; break;
      case 0x0292: cp = 0x01b7; break;
      case 0x01c6: cp = 0x01c4; break;
      case 0x01c9: cp = 0x01c7; break;
      case 0x01cc: cp = 0x01ca; break;
      case 0x01f3: cp = 0x01f1; break;
      case 0x01bf: cp = 0x01f7; break;
      case 0x0188: cp = 0x0187; break;
      case 0x018c: cp = 0x018b; break;
      case 0x0192: cp = 0x0191; break;
      case 0x0199: cp = 0x0198; break;
      case 0x01a8: cp = 0x01a7; break;
      case 0x01ad: cp = 0x01ac; break;
      case 0x01b0: cp = 0x01af; break;
      case 0x01b9: cp = 0x01b8; break;
      case 0x01bd: cp = 0x01bc; break;
      case 0x01f5: cp = 0x01f4; break;
      case 0x023c: cp = 0x023b; break;
      case 0x0242: cp = 0x0241; break;
      case 0x037b: cp = 0x03fd; break;
      case 0x037c: cp = 0x03fe; break;
      case 0x037d: cp = 0x03ff; break;
      case 0x03f3: cp = 0x037f; break;
      case 0x03ac: cp = 0x0386; break;
      case 0x03ad: cp = 0x0388; break;
      case 0x03ae: cp = 0x0389; break;
      case 0x03af: cp = 0x038a; break;
      case 0x03cc: cp = 0x038c; break;
      case 0x03cd: cp = 0x038e; break;
      case 0x03ce: cp = 0x038f; break;
      case 0x0371: cp = 0x0370; break;
      case 0x0373: cp = 0x0372; break;
      case 0x0377: cp = 0x0376; break;
      case 0x03d1: cp = 0x03f4; break;
      case 0x03d7: cp = 0x03cf; break;
      case 0x03f2: cp = 0x03f9; break;
      case 0x03f8: cp = 0x03f7; break;
      case 0x03fb: cp = 0x03fa; break;
      };
    }
  
    return cp;
  }
  
  #undef utf8_restrict
  #undef utf8_null
  
  #ifdef __cplusplus
  } // extern "C"
  #endif
  
  #if defined(__clang__)
  #pragma clang diagnostic pop
  #endif
  
  #endif // SHEREDOM_UTF8_H_INCLUDED
  

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