Horspool, KMP et al are optimal at minimizing the number of byte-comparisons. However, that's not the bottleneck on a modern processor. On an x86/64 processor, your string is being loaded into L1 cache in cache-line-width chunks (typically 64 bytes). No matter how clever your algorithm is, unless it gives you strides that are larger than that, you gain nothing; and the more complicated Horspool code is (at least one table lookup) can't compete.
Furthermore, you're stuck with the "C" string constraint of null-termination: SOMEWHERE the code has to examine every byte.
strstr is expected to be optimal for a wide range of cases; e.g. searching for tiny strings like "\r\n" in a short string, as well as much longer ones where some smarter algorithm might have a hope. The basic strchr/memcmp loop is pretty hard to beat across the whole range of likely inputs.
Pretty much all x86-compatible processors since 2003 have supported SSE2. If you disassembled strlen/x86 for glibc, you may have noticed that it uses some SSE2 PCMPEQ and MOVMASK operations to search for the null terminator 16 bytes at a time. The solution is so efficient that it beats the obvious super-simple loop, for anything longer than the empty string.
I took that idea and came up with a strstr that beats glibc's strstr for all cases greater than 1 byte --- where the relative difference is pretty much moot. If you're interested, check out:
If you care to see a non-SSE2 solution that dominates strstr for target strings of more than 15 bytes, check out:
... which makes use of multibyte comparisons rather than strchr, to find a point at which to do a memcmp.
BTW you've probably figured out by now that the x86 REP SCASB/REP CMPSB ops fall on their ass for anything longer than 32 bytes, and are not much improvement for shorter strings. Wish Intel had devoted a little more attention to that, than to adding SSE4.2 "string" ops.
For strings large enough to matter, my perf tests show that BNDM is better than Horspool, across the board. BNDM is more tolerant of "pathological" cases, such as targets that heavily repeat the last byte of a pattern. BNDM can also make use of SSE2 (128bit registers) in a way that competes with 32bit registers in efficiency and start-up cost. Source code at: