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I have two questions regarding the implementation of strlen in string.h in glibc.

  1. The implementation uses a magic number with 'holes'. I am not able to understand how this works. Can someone please help me understand this snippet:

    size_t
    strlen (const char *str)
    {
       const char *char_ptr;
       const unsigned long int *longword_ptr;
       unsigned long int longword, himagic, lomagic;
    
       /* Handle the first few characters by reading one character at a time.
          Do this until CHAR_PTR is aligned on a longword boundary.  */
       for (char_ptr = str; ((unsigned long int) char_ptr
                 & (sizeof (longword) - 1)) != 0;
            ++char_ptr)
         if (*char_ptr == '\0')
           return char_ptr - str;
    
       /* All these elucidatory comments refer to 4-byte longwords,
          but the theory applies equally well to 8-byte longwords.  */
    
       longword_ptr = (unsigned long int *) char_ptr;
    
       /* Bits 31, 24, 16, and 8 of this number are zero.  Call these bits
          the "holes."  Note that there is a hole just to the left of
          each byte, with an extra at the end:
    
          bits:  01111110 11111110 11111110 11111111
          bytes: AAAAAAAA BBBBBBBB CCCCCCCC DDDDDDDD
    
          The 1-bits make sure that carries propagate to the next 0-bit.
          The 0-bits provide holes for carries to fall into.  */
    
        himagic = 0x80808080L;
           lomagic = 0x01010101L;
           if (sizeof (longword) > 4)
           {
               /* 64-bit version of the magic.  */
               /* Do the shift in two steps to avoid a warning if long has 32 bits.  */
               himagic = ((himagic << 16) << 16) | himagic;
                 lomagic = ((lomagic << 16) << 16) | lomagic;
             }
           if (sizeof (longword) > 8)
             abort ();
    
           /* Instead of the traditional loop which tests each character,
              we will test a longword at a time.  The tricky part is testing
              if *any of the four* bytes in the longword in question are zero.  */
           for (;;)
             {
               longword = *longword_ptr++;
    
               if (((longword - lomagic) & ~longword & himagic) != 0)
             {
               /* Which of the bytes was the zero?  If none of them were, it was
                  a misfire; continue the search.  */
    
               const char *cp = (const char *) (longword_ptr - 1);
    
               if (cp[0] == 0)
                 return cp - str;
               if (cp[1] == 0)
                 return cp - str + 1;
               if (cp[2] == 0)
                 return cp - str + 2;
               if (cp[3] == 0)
                 return cp - str + 3;
               if (sizeof (longword) > 4)
                 {
                   if (cp[4] == 0)
                 return cp - str + 4;
                   if (cp[5] == 0)
                 return cp - str + 5;
                   if (cp[6] == 0)
                 return cp - str + 6;
         if (cp[7] == 0)
          return cp - str + 7;
    }}}
    

    What is the magic number being used for?

  2. Why not simply increment pointer until NULL character and return count? Is this approach faster? Why is it so?

1
  • 1
    On most architectures, glibc will use even faster functions. On modern Intel chips, for example, it uses SIMD extensions to vectorize the check.
    – rici
    Jan 6 '16 at 21:44
16

This is used to look at 4 bytes (32 bits) or even 8 (64 bits) in one go, to check if one of them is zero (end of string), instead of checking each byte individually.

Here is one example to check for a null byte:

unsigned int v; // 32-bit word to check if any 8-bit byte in it is 0
bool hasZeroByte = ~((((v & 0x7F7F7F7F) + 0x7F7F7F7F) | v) | 0x7F7F7F7F);

For some more see Bit Twiddling Hacks.

The one used here (32-bit example):

There is yet a faster method — use hasless(v, 1), which is defined below; it works in 4 operations and requires no subsquent verification. It simplifies to

#define haszero(v) (((v) - 0x01010101UL) & ~(v) & 0x80808080UL)

The subexpression (v - 0x01010101UL), evaluates to a high bit set in any byte whenever the corresponding byte in v is zero or greater than 0x80. The sub-expression ~v & 0x80808080UL evaluates to high bits set in bytes where the byte of v doesn't have its high bit set (so the byte was less than 0x80). Finally, by ANDing these two sub-expressions the result is the high bits set where the bytes in v were zero, since the high bits set due to a value greater than 0x80 in the first sub-expression are masked off by the second.

Looking at one byte at a time costs at least as much cpu cycles as looking at a full interger value (register wide). In this algorithm, full integers are checked to see if they contain a zero. If not, little instructions are used, and a jump can be made to the next full integer. If there is a zero byte inside, a further check is done to see at what exact position it was.

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  • 2
    In addition, what the gcc strlen implementation does is optimize to take advantage of architectures where 8-byte integers are supported. Above you are limited to looking for a null in 4-bytes at a time. The if (sizeof (longword) > 4) comparison in strlen extends the comparison for an additional 4-bytes. The benefit either way is improved strlen performance for strings longer than approximately 32-chars. (above what you get with a char-by-char check). Good answer. Jan 7 '16 at 7:53

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