/* Return the offset of one string within another. Copyright (C) 1994-2017 Free Software Foundation, Inc. This file is part of the GNU C Library. The GNU C Library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. The GNU C Library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with the GNU C Library; if not, see . */ #ifndef _LIBC # include #endif #include #define RETURN_TYPE char * #define AVAILABLE(h, h_l, j, n_l) \ (((j) + (n_l) <= (h_l)) \ || ((h_l) += __strnlen ((void*)((h) + (h_l)), (n_l) + 512), \ (j) + (n_l) <= (h_l))) #include "str-two-way.h" #undef strstr #ifndef STRSTR #define STRSTR strstr #endif static inline char * strstr2 (const unsigned char *hs, const unsigned char *ne) { uint32_t h1 = (ne[0] << 16) | ne[1]; uint32_t h2 = 0; for (int c = hs[0]; h1 != h2 && c != 0; c = *++hs) h2 = (h2 << 16) | c; return h1 == h2 ? (char *)hs - 2 : NULL; } static inline char * strstr3 (const unsigned char *hs, const unsigned char *ne) { uint32_t h1 = ((uint32_t)ne[0] << 24) | (ne[1] << 16) | (ne[2] << 8); uint32_t h2 = 0; for (int c = hs[0]; h1 != h2 && c != 0; c = *++hs) h2 = (h2 | c) << 8; return h1 == h2 ? (char *)hs - 3 : NULL; } /* Hash character pairs so a small shift table can be used. All bits of p[0] are included, but not all bits from p[-1]. So if two equal hashes match on p[-1], p[0] matches too. Hash collisions are harmless and result in smaller shifts. */ #define hash2(p) (((size_t)(p)[0] - ((size_t)(p)[-1] << 3)) % sizeof (shift)) /* Fast strstr algorithm with guaranteed linear-time performance. Small needles up to size 3 use a dedicated linear search. Longer needles up to size 256 use a novel modified Horspool algorithm. It hashes pairs of characters to quickly skip past mismatches. The main search loop only exits if the last 2 characters match, avoiding unnecessary calls to memcmp and allowing for a larger skip if there is no match. A self-adapting filtering check is used to quickly detect mismatches in long needles. By limiting the needle length to 256, the shift table can be reduced to 8 bits per entry, lowering preprocessing overhead and minimizing cache effects. The limit also implies worst-case performance is linear. Needles larger than 256 characters use the linear-time Two-Way algorithm. */ char * STRSTR (const char *haystack, const char *needle) { const unsigned char *hs = (const unsigned char *) haystack; const unsigned char *ne = (const unsigned char *) needle; /* Handle short needle special cases first. */ if (ne[0] == '\0') return (char *)hs; hs = (const unsigned char *)strchr ((const char*)hs, ne[0]); if (hs == NULL || ne[1] == '\0') return (char*)hs; if (ne[2] == '\0') return strstr2 (hs, ne); if (ne[3] == '\0') return strstr3 (hs, ne); /* Ensure haystack length is at least as long as needle length. Since a match may occur early on in a huge haystack, use strnlen and read ahead a few cachelines for improved performance. */ size_t ne_len = strlen ((const char*)ne); size_t hs_len = __strnlen ((const char*)hs, ne_len | 512); if (hs_len < ne_len) return NULL; /* Check whether we have a match. This improves performance since we avoid initialization overheads. */ if (memcmp (hs, ne, ne_len) == 0) return (char *) hs; /* Use Two-Way algorithm for very long needles. */ if (__glibc_unlikely (ne_len > 256)) return two_way_long_needle (hs, hs_len, ne, ne_len); const unsigned char *end = hs + hs_len - ne_len; uint8_t shift[256]; size_t tmp, shift1; size_t m1 = ne_len - 1; size_t offset = 0; /* Initialize bad character shift hash table. */ memset (shift, 0, sizeof (shift)); for (int i = 1; i < m1; i++) shift[hash2 (ne + i)] = i; /* Shift1 is the amount we can skip after matching the hash of the needle end but not the full needle. */ shift1 = m1 - shift[hash2 (ne + m1)]; shift[hash2 (ne + m1)] = m1; while (1) { if (__glibc_unlikely (hs > end)) { end += __strnlen ((const char*)end + m1 + 1, 2048); if (hs > end) return NULL; } /* Skip past character pairs not in the needle. */ do { hs += m1; tmp = shift[hash2 (hs)]; } while (tmp == 0 && hs <= end); /* If the match is not at the end of the needle, shift to the end and continue until we match the hash of the needle end. */ hs -= tmp; if (tmp < m1) continue; /* Hash of the last 2 characters matches. If the needle is long, try to quickly filter out mismatches. */ if (m1 < 15 || memcmp (hs + offset, ne + offset, 8) == 0) { if (memcmp (hs, ne, m1) == 0) return (void *) hs; /* Adjust filter offset when it doesn't find the mismatch. */ offset = (offset >= 8 ? offset : m1) - 8; } /* Skip based on matching the hash of the needle end. */ hs += shift1; } } libc_hidden_builtin_def (strstr)