13

I am reading "Write Great Code Volume 2" and it shows the following strlen impelementation:

int myStrlen( char *s )
{
    char *start;
    start = s;
    while( *s != 0 )
    {
        ++s;
    }
    return s - start;
}

the book says that this implementation is typical for an inexperienced C programmer. I have been coding in C for the past 11 years and i can't see how to write a function better than this in C(i can think of writing better thing in assembly). How is it possible to write code better than this in C? I looked the standard library implementation of the strlen function in glibc and I couldn't understand most part of it. Where can I find better information on how to write highly optimized code?

7
  • 3
    Are you sure its a optimization issue? Or just the standard security issue? Jul 5, 2011 at 14:33
  • 2
    @Victor Don't believe everything you read. That function is fast enough.
    – cnicutar
    Jul 5, 2011 at 14:33
  • 2
    I once wrote strlen() in assembler for an i386 system which used the CPU string (REP) opcodes, and ran 6x faster than optimized C code. Jul 5, 2011 at 15:28
  • @Loadmaster: can you post this code please?
    – Victor
    Jul 5, 2011 at 15:44
  • 2
    I'd object to the cast of ptrdiff_t to int yea you're probably not passing 2GB strings to strlen() but still it's sloppy. Also the compiler might produce better code from int i=0; while(s[i]) i++; return i; because it can tell more about what you're doing with the pointer (ie it can analyze that loop better).
    – Spudd86
    Jul 5, 2011 at 20:38

7 Answers 7

15

From Optimising strlen(), a blogpost by Colm MacCarthaigh:

Unfortunately in C, we’re doomed to an O(n) implementation, best case, but we’re still not done … we can do something about the very size of n.

It gives good example in what direction you can work to speed it up. And another quote from it

Sometimes going really really fast just makes you really really insane.

0
3

Victor, take a look at this:
http://en.wikipedia.org/wiki/Strlen#Implementation

P.S. The reason you don't understand the glibc version is probably because it uses bit shifting to find the \0.

5
  • 1
    My guess is, that with a moderate compiler, this will produce exactly the same byte-code as the OPs implementation... Jul 5, 2011 at 14:38
  • @Martin: you cannot check a 'word' against zero, that won't work Jul 5, 2011 at 14:42
  • @Victor: Sorry, I didn't mean to cast aspersions on your programming ability. If you're looking for an explanation of the glibc implementation, post a question and I'm sure smarter people than me will be able to explain it.
    – gkrogers
    Jul 5, 2011 at 15:14
  • No problem, I didn't felt offended, I was just commenting.
    – Victor
    Jul 5, 2011 at 16:02
  • The special case x86 instructions mention are in fact slower than a loop on modern CPUs IIRC
    – Spudd86
    Jul 5, 2011 at 20:55
3

For starters, this is worthless for encodings like UTF-8... that is, calculating the number of characters in an UTF-8 string is more complicated, whereas the number of bytes is, of course, just as easy to calculate as in, say, an ASCII string.

In general, you can optimize on some platforms by reading into larger registers. Since the other links posted so far don't have an example of that, here's a bit of pseudo-pseudocode for lower endian:

int size = 0;
int x;
int *caststring = (int *) yourstring;
while (int x = *caststring++) {
  if (!(x & 0xff)) /* first byte in this int-sized package is 0 */ return size;
  else if (!(x & 0xff00)) /* second byte etc. */ return size+1;
  /* rinse and repeat depending on target architecture, i.e. twice more for 32 bit */
  size += sizeof (int);
}
4
  • That's probably won't improve peformance, I have a feeling it will just make it worse. Jul 5, 2011 at 14:51
  • 1
    @yi_H: Disadvantages: one extra AND per byte. Advantages: 75% less loads from memory, 75% less jumps. Which side wins the contest is almost certainly architecture-specific. I have no concrete knowledge of how it would perform on which architectures, so you may well be right. But you might just as well be wrong. ;) Jul 5, 2011 at 15:02
  • 1
    it's actually 75% less load from the cache line, as these are consecutive bytes. Jul 5, 2011 at 15:34
  • Yep. Totally correct. Perhaps I should reconsider that staying awake thing. Jul 5, 2011 at 15:43
3

As others have pointed out, a faster algorithm reads entire words instead of individual characters and uses bitwise operations to find the terminating null. Be mindful of word-aligning your pointer if you take this approach, as some CPU architectures won't let you read words from an unaligned address (and it's a great way to trigger a segfault even on architectures that don't require alignment).

Bottom line:

Great code emphasizes readability over speed in all but the most performance-critical cases. Write your code as clearly as you can and only optimize the parts that prove to be bottlenecks.

2
  • I guess argument "great code is reader-friendly code" doesn't hold in case of C Std library that aims for performance. Jul 6, 2011 at 12:53
  • Since the std libraries are so widely and frequently used, the "performance-critical" exception is appropriate. Still, most of them could use better documentation... Jul 6, 2011 at 13:16
1

Reading a variable that is not of the same size as the machine data bus size is expensive, because the machine can only read variables of that size. Therefore, whenever something of different size (let's say smaller) is requested, the machine must do work to make it look like a variable of the requested size (like shifting the bits). So you better read the data in machine sized words, and then use the AND operation to check for 0s. Also, when scanning through the string, make sure you start at an aligned start address.

1

Answering OP's question about where to find suggestions how to write code for performance, here's link to MIT OpenCourse on writing Optimized C Code (look for "Materials" link on the left of page).

1

The following should be faster than the naive algorithm and work for 32/64 bit.

union intptr {
    char* c;
    long* l;
#define LSIZE sizeof(long)
};

#define aligned_(x, a) \
    ((unsigned long) (x) % (a) == 0)

#define punpktt_(x, from, to) \
    ((to) (-1)/(from) (-1)*(from) (x))
#define punpkbl_(x) \
    punpktt_(x, unsigned char, unsigned long)

#define plessbl_(x, y) \
    (((x) - punpkbl_(y)) & ~(x) & punpkbl_(0x80))
#define pzerobl_(x) \
    plessbl_(x, 1)

static inline unsigned long maskffs_(unsigned long x)
{
    unsigned long acc = 0x00010203UL;
    if (LSIZE == 8)
       acc = ((acc << 16) << 16) | 0x04050607UL;
    return ((x & -x) >> 7) * acc >> (LSIZE*8-8);
}

size_t strlen(const char* base)
{
    union intptr p = { (char*) base };
    unsigned long mask;

    for ( ; !aligned_(p.c, LSIZE); p.c++ )
        if (*p.c == 0)
            return p.c - base;

    while ( !(mask = pzerobl_(*p.l)) )
        p.l++;
    return p.c - base + maskffs_(mask);
}

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