/* Substring test for UTF-8/UTF-16/UTF-32 strings. Copyright (C) 1999, 2002, 2006, 2010-2015 Free Software Foundation, Inc. Written by Bruno Haible , 2002, 2005. This program 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 3 of the License, or (at your option) any later version. This program 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 this program. If not, see . */ UNIT * FUNC (const UNIT *haystack, const UNIT *needle) { UNIT first = needle[0]; /* Is needle empty? */ if (first == 0) return (UNIT *) haystack; /* Is needle nearly empty (only one unit)? */ if (needle[1] == 0) return U_STRCHR (haystack, first); #ifdef U_STRMBTOUC /* Is needle nearly empty (only one character)? */ { ucs4_t first_uc; int count = U_STRMBTOUC (&first_uc, needle); if (count > 0 && needle[count] == 0) return U_STRCHR (haystack, first_uc); } #endif #if UNIT_IS_UINT8_T return (uint8_t *) strstr ((const char *) haystack, (const char *) needle); #else { /* Minimizing the worst-case complexity: Let n = U_STRLEN(haystack), m = U_STRLEN(needle). The naïve algorithm is O(n*m) worst-case. The Knuth-Morris-Pratt algorithm is O(n) worst-case but it needs a memory allocation. To achieve linear complexity and yet amortize the cost of the memory allocation, we activate the Knuth-Morris-Pratt algorithm only once the naïve algorithm has already run for some time; more precisely, when - the outer loop count is >= 10, - the average number of comparisons per outer loop is >= 5, - the total number of comparisons is >= m. But we try it only once. If the memory allocation attempt failed, we don't retry it. */ bool try_kmp = true; size_t outer_loop_count = 0; size_t comparison_count = 0; size_t last_ccount = 0; /* last comparison count */ const UNIT *needle_last_ccount = needle; /* = needle + last_ccount */ /* Speed up the following searches of needle by caching its first character. */ UNIT b = *needle++; for (;; haystack++) { if (*haystack == 0) /* No match. */ return NULL; /* See whether it's advisable to use an asymptotically faster algorithm. */ if (try_kmp && outer_loop_count >= 10 && comparison_count >= 5 * outer_loop_count) { /* See if needle + comparison_count now reaches the end of needle. */ if (needle_last_ccount != NULL) { needle_last_ccount += U_STRNLEN (needle_last_ccount, comparison_count - last_ccount); if (*needle_last_ccount == 0) needle_last_ccount = NULL; last_ccount = comparison_count; } if (needle_last_ccount == NULL) { /* Try the Knuth-Morris-Pratt algorithm. */ const UNIT *result; bool success = knuth_morris_pratt (haystack, needle - 1, U_STRLEN (needle - 1), &result); if (success) return (UNIT *) result; try_kmp = false; } } outer_loop_count++; comparison_count++; if (*haystack == b) /* The first character matches. */ { const UNIT *rhaystack = haystack + 1; const UNIT *rneedle = needle; for (;; rhaystack++, rneedle++) { if (*rneedle == 0) /* Found a match. */ return (UNIT *) haystack; if (*rhaystack == 0) /* No match. */ return NULL; comparison_count++; if (*rhaystack != *rneedle) /* Nothing in this round. */ break; } } } } #endif }