| /* stringlib: fastsearch implementation */ |
| |
| #define STRINGLIB_FASTSEARCH_H |
| |
| /* fast search/count implementation, based on a mix between boyer- |
| moore and horspool, with a few more bells and whistles on the top. |
| for some more background, see: http://effbot.org/zone/stringlib.htm */ |
| |
| /* note: fastsearch may access s[n], which isn't a problem when using |
| Python's ordinary string types, but may cause problems if you're |
| using this code in other contexts. also, the count mode returns -1 |
| if there cannot possibly be a match in the target string, and 0 if |
| it has actually checked for matches, but didn't find any. callers |
| beware! */ |
| |
| /* If the strings are long enough, use Crochemore and Perrin's Two-Way |
| algorithm, which has worst-case O(n) runtime and best-case O(n/k). |
| Also compute a table of shifts to achieve O(n/k) in more cases, |
| and often (data dependent) deduce larger shifts than pure C&P can |
| deduce. */ |
| |
| #define FAST_COUNT 0 |
| #define FAST_SEARCH 1 |
| #define FAST_RSEARCH 2 |
| |
| #if LONG_BIT >= 128 |
| #define STRINGLIB_BLOOM_WIDTH 128 |
| #elif LONG_BIT >= 64 |
| #define STRINGLIB_BLOOM_WIDTH 64 |
| #elif LONG_BIT >= 32 |
| #define STRINGLIB_BLOOM_WIDTH 32 |
| #else |
| #error "LONG_BIT is smaller than 32" |
| #endif |
| |
| #define STRINGLIB_BLOOM_ADD(mask, ch) \ |
| ((mask |= (1UL << ((ch) & (STRINGLIB_BLOOM_WIDTH -1))))) |
| #define STRINGLIB_BLOOM(mask, ch) \ |
| ((mask & (1UL << ((ch) & (STRINGLIB_BLOOM_WIDTH -1))))) |
| |
| #if STRINGLIB_SIZEOF_CHAR == 1 |
| # define MEMCHR_CUT_OFF 15 |
| #else |
| # define MEMCHR_CUT_OFF 40 |
| #endif |
| |
| Py_LOCAL_INLINE(Py_ssize_t) |
| STRINGLIB(find_char)(const STRINGLIB_CHAR* s, Py_ssize_t n, STRINGLIB_CHAR ch) |
| { |
| const STRINGLIB_CHAR *p, *e; |
| |
| p = s; |
| e = s + n; |
| if (n > MEMCHR_CUT_OFF) { |
| #if STRINGLIB_SIZEOF_CHAR == 1 |
| p = memchr(s, ch, n); |
| if (p != NULL) |
| return (p - s); |
| return -1; |
| #else |
| /* use memchr if we can choose a needle without too many likely |
| false positives */ |
| const STRINGLIB_CHAR *s1, *e1; |
| unsigned char needle = ch & 0xff; |
| /* If looking for a multiple of 256, we'd have too |
| many false positives looking for the '\0' byte in UCS2 |
| and UCS4 representations. */ |
| if (needle != 0) { |
| do { |
| void *candidate = memchr(p, needle, |
| (e - p) * sizeof(STRINGLIB_CHAR)); |
| if (candidate == NULL) |
| return -1; |
| s1 = p; |
| p = (const STRINGLIB_CHAR *) |
| _Py_ALIGN_DOWN(candidate, sizeof(STRINGLIB_CHAR)); |
| if (*p == ch) |
| return (p - s); |
| /* False positive */ |
| p++; |
| if (p - s1 > MEMCHR_CUT_OFF) |
| continue; |
| if (e - p <= MEMCHR_CUT_OFF) |
| break; |
| e1 = p + MEMCHR_CUT_OFF; |
| while (p != e1) { |
| if (*p == ch) |
| return (p - s); |
| p++; |
| } |
| } |
| while (e - p > MEMCHR_CUT_OFF); |
| } |
| #endif |
| } |
| while (p < e) { |
| if (*p == ch) |
| return (p - s); |
| p++; |
| } |
| return -1; |
| } |
| |
| Py_LOCAL_INLINE(Py_ssize_t) |
| STRINGLIB(rfind_char)(const STRINGLIB_CHAR* s, Py_ssize_t n, STRINGLIB_CHAR ch) |
| { |
| const STRINGLIB_CHAR *p; |
| #ifdef HAVE_MEMRCHR |
| /* memrchr() is a GNU extension, available since glibc 2.1.91. |
| it doesn't seem as optimized as memchr(), but is still quite |
| faster than our hand-written loop below */ |
| |
| if (n > MEMCHR_CUT_OFF) { |
| #if STRINGLIB_SIZEOF_CHAR == 1 |
| p = memrchr(s, ch, n); |
| if (p != NULL) |
| return (p - s); |
| return -1; |
| #else |
| /* use memrchr if we can choose a needle without too many likely |
| false positives */ |
| const STRINGLIB_CHAR *s1; |
| Py_ssize_t n1; |
| unsigned char needle = ch & 0xff; |
| /* If looking for a multiple of 256, we'd have too |
| many false positives looking for the '\0' byte in UCS2 |
| and UCS4 representations. */ |
| if (needle != 0) { |
| do { |
| void *candidate = memrchr(s, needle, |
| n * sizeof(STRINGLIB_CHAR)); |
| if (candidate == NULL) |
| return -1; |
| n1 = n; |
| p = (const STRINGLIB_CHAR *) |
| _Py_ALIGN_DOWN(candidate, sizeof(STRINGLIB_CHAR)); |
| n = p - s; |
| if (*p == ch) |
| return n; |
| /* False positive */ |
| if (n1 - n > MEMCHR_CUT_OFF) |
| continue; |
| if (n <= MEMCHR_CUT_OFF) |
| break; |
| s1 = p - MEMCHR_CUT_OFF; |
| while (p > s1) { |
| p--; |
| if (*p == ch) |
| return (p - s); |
| } |
| n = p - s; |
| } |
| while (n > MEMCHR_CUT_OFF); |
| } |
| #endif |
| } |
| #endif /* HAVE_MEMRCHR */ |
| p = s + n; |
| while (p > s) { |
| p--; |
| if (*p == ch) |
| return (p - s); |
| } |
| return -1; |
| } |
| |
| #undef MEMCHR_CUT_OFF |
| |
| /* Change to a 1 to see logging comments walk through the algorithm. */ |
| #if 0 && STRINGLIB_SIZEOF_CHAR == 1 |
| # define LOG(...) printf(__VA_ARGS__) |
| # define LOG_STRING(s, n) printf("\"%.*s\"", n, s) |
| #else |
| # define LOG(...) |
| # define LOG_STRING(s, n) |
| #endif |
| |
| Py_LOCAL_INLINE(Py_ssize_t) |
| STRINGLIB(_lex_search)(const STRINGLIB_CHAR *needle, Py_ssize_t len_needle, |
| Py_ssize_t *return_period, int invert_alphabet) |
| { |
| /* Do a lexicographic search. Essentially this: |
| >>> max(needle[i:] for i in range(len(needle)+1)) |
| Also find the period of the right half. */ |
| Py_ssize_t max_suffix = 0; |
| Py_ssize_t candidate = 1; |
| Py_ssize_t k = 0; |
| // The period of the right half. |
| Py_ssize_t period = 1; |
| |
| while (candidate + k < len_needle) { |
| // each loop increases candidate + k + max_suffix |
| STRINGLIB_CHAR a = needle[candidate + k]; |
| STRINGLIB_CHAR b = needle[max_suffix + k]; |
| // check if the suffix at candidate is better than max_suffix |
| if (invert_alphabet ? (b < a) : (a < b)) { |
| // Fell short of max_suffix. |
| // The next k + 1 characters are non-increasing |
| // from candidate, so they won't start a maximal suffix. |
| candidate += k + 1; |
| k = 0; |
| // We've ruled out any period smaller than what's |
| // been scanned since max_suffix. |
| period = candidate - max_suffix; |
| } |
| else if (a == b) { |
| if (k + 1 != period) { |
| // Keep scanning the equal strings |
| k++; |
| } |
| else { |
| // Matched a whole period. |
| // Start matching the next period. |
| candidate += period; |
| k = 0; |
| } |
| } |
| else { |
| // Did better than max_suffix, so replace it. |
| max_suffix = candidate; |
| candidate++; |
| k = 0; |
| period = 1; |
| } |
| } |
| *return_period = period; |
| return max_suffix; |
| } |
| |
| Py_LOCAL_INLINE(Py_ssize_t) |
| STRINGLIB(_factorize)(const STRINGLIB_CHAR *needle, |
| Py_ssize_t len_needle, |
| Py_ssize_t *return_period) |
| { |
| /* Do a "critical factorization", making it so that: |
| >>> needle = (left := needle[:cut]) + (right := needle[cut:]) |
| where the "local period" of the cut is maximal. |
| |
| The local period of the cut is the minimal length of a string w |
| such that (left endswith w or w endswith left) |
| and (right startswith w or w startswith left). |
| |
| The Critical Factorization Theorem says that this maximal local |
| period is the global period of the string. |
| |
| Crochemore and Perrin (1991) show that this cut can be computed |
| as the later of two cuts: one that gives a lexicographically |
| maximal right half, and one that gives the same with the |
| with respect to a reversed alphabet-ordering. |
| |
| This is what we want to happen: |
| >>> x = "GCAGAGAG" |
| >>> cut, period = factorize(x) |
| >>> x[:cut], (right := x[cut:]) |
| ('GC', 'AGAGAG') |
| >>> period # right half period |
| 2 |
| >>> right[period:] == right[:-period] |
| True |
| |
| This is how the local period lines up in the above example: |
| GC | AGAGAG |
| AGAGAGC = AGAGAGC |
| The length of this minimal repetition is 7, which is indeed the |
| period of the original string. */ |
| |
| Py_ssize_t cut1, period1, cut2, period2, cut, period; |
| cut1 = STRINGLIB(_lex_search)(needle, len_needle, &period1, 0); |
| cut2 = STRINGLIB(_lex_search)(needle, len_needle, &period2, 1); |
| |
| // Take the later cut. |
| if (cut1 > cut2) { |
| period = period1; |
| cut = cut1; |
| } |
| else { |
| period = period2; |
| cut = cut2; |
| } |
| |
| LOG("split: "); LOG_STRING(needle, cut); |
| LOG(" + "); LOG_STRING(needle + cut, len_needle - cut); |
| LOG("\n"); |
| |
| *return_period = period; |
| return cut; |
| } |
| |
| #define SHIFT_TYPE uint8_t |
| #define NOT_FOUND ((1U<<(8*sizeof(SHIFT_TYPE))) - 1U) |
| #define SHIFT_OVERFLOW (NOT_FOUND - 1U) |
| |
| #define TABLE_SIZE_BITS 6 |
| #define TABLE_SIZE (1U << TABLE_SIZE_BITS) |
| #define TABLE_MASK (TABLE_SIZE - 1U) |
| |
| typedef struct STRINGLIB(_pre) { |
| const STRINGLIB_CHAR *needle; |
| Py_ssize_t len_needle; |
| Py_ssize_t cut; |
| Py_ssize_t period; |
| int is_periodic; |
| SHIFT_TYPE table[TABLE_SIZE]; |
| } STRINGLIB(prework); |
| |
| |
| Py_LOCAL_INLINE(void) |
| STRINGLIB(_preprocess)(const STRINGLIB_CHAR *needle, Py_ssize_t len_needle, |
| STRINGLIB(prework) *p) |
| { |
| p->needle = needle; |
| p->len_needle = len_needle; |
| p->cut = STRINGLIB(_factorize)(needle, len_needle, &(p->period)); |
| assert(p->period + p->cut <= len_needle); |
| p->is_periodic = (0 == memcmp(needle, |
| needle + p->period, |
| p->cut * STRINGLIB_SIZEOF_CHAR)); |
| if (p->is_periodic) { |
| assert(p->cut <= len_needle/2); |
| assert(p->cut < p->period); |
| } |
| else { |
| // A lower bound on the period |
| p->period = Py_MAX(p->cut, len_needle - p->cut) + 1; |
| } |
| // Now fill up a table |
| memset(&(p->table[0]), 0xff, TABLE_SIZE*sizeof(SHIFT_TYPE)); |
| assert(p->table[0] == NOT_FOUND); |
| assert(p->table[TABLE_MASK] == NOT_FOUND); |
| for (Py_ssize_t i = 0; i < len_needle; i++) { |
| Py_ssize_t shift = len_needle - i; |
| if (shift > SHIFT_OVERFLOW) { |
| shift = SHIFT_OVERFLOW; |
| } |
| p->table[needle[i] & TABLE_MASK] = Py_SAFE_DOWNCAST(shift, |
| Py_ssize_t, |
| SHIFT_TYPE); |
| } |
| } |
| |
| Py_LOCAL_INLINE(Py_ssize_t) |
| STRINGLIB(_two_way)(const STRINGLIB_CHAR *haystack, Py_ssize_t len_haystack, |
| STRINGLIB(prework) *p) |
| { |
| // Crochemore and Perrin's (1991) Two-Way algorithm. |
| // See http://www-igm.univ-mlv.fr/~lecroq/string/node26.html#SECTION00260 |
| Py_ssize_t len_needle = p->len_needle; |
| Py_ssize_t cut = p->cut; |
| Py_ssize_t period = p->period; |
| const STRINGLIB_CHAR *needle = p->needle; |
| const STRINGLIB_CHAR *window = haystack; |
| const STRINGLIB_CHAR *last_window = haystack + len_haystack - len_needle; |
| SHIFT_TYPE *table = p->table; |
| LOG("===== Two-way: \"%s\" in \"%s\". =====\n", needle, haystack); |
| |
| if (p->is_periodic) { |
| LOG("Needle is periodic.\n"); |
| Py_ssize_t memory = 0; |
| periodicwindowloop: |
| while (window <= last_window) { |
| Py_ssize_t i = Py_MAX(cut, memory); |
| |
| // Visualize the line-up: |
| LOG("> "); LOG_STRING(haystack, len_haystack); |
| LOG("\n> "); LOG("%*s", window - haystack, ""); |
| LOG_STRING(needle, len_needle); |
| LOG("\n> "); LOG("%*s", window - haystack + i, ""); |
| LOG(" ^ <-- cut\n"); |
| |
| if (window[i] != needle[i]) { |
| // Sunday's trick: if we're going to jump, we might |
| // as well jump to line up the character *after* the |
| // current window. |
| STRINGLIB_CHAR first_outside = window[len_needle]; |
| SHIFT_TYPE shift = table[first_outside & TABLE_MASK]; |
| if (shift == NOT_FOUND) { |
| LOG("\"%c\" not found. Skipping entirely.\n", |
| first_outside); |
| window += len_needle + 1; |
| } |
| else { |
| LOG("Shifting to line up \"%c\".\n", first_outside); |
| Py_ssize_t memory_shift = i - cut + 1; |
| window += Py_MAX(shift, memory_shift); |
| } |
| memory = 0; |
| goto periodicwindowloop; |
| } |
| for (i = i + 1; i < len_needle; i++) { |
| if (needle[i] != window[i]) { |
| LOG("Right half does not match. Jump ahead by %d.\n", |
| i - cut + 1); |
| window += i - cut + 1; |
| memory = 0; |
| goto periodicwindowloop; |
| } |
| } |
| for (i = memory; i < cut; i++) { |
| if (needle[i] != window[i]) { |
| LOG("Left half does not match. Jump ahead by period %d.\n", |
| period); |
| window += period; |
| memory = len_needle - period; |
| goto periodicwindowloop; |
| } |
| } |
| LOG("Left half matches. Returning %d.\n", |
| window - haystack); |
| return window - haystack; |
| } |
| } |
| else { |
| LOG("Needle is not periodic.\n"); |
| assert(cut < len_needle); |
| STRINGLIB_CHAR needle_cut = needle[cut]; |
| windowloop: |
| while (window <= last_window) { |
| |
| // Visualize the line-up: |
| LOG("> "); LOG_STRING(haystack, len_haystack); |
| LOG("\n> "); LOG("%*s", window - haystack, ""); |
| LOG_STRING(needle, len_needle); |
| LOG("\n> "); LOG("%*s", window - haystack + cut, ""); |
| LOG(" ^ <-- cut\n"); |
| |
| if (window[cut] != needle_cut) { |
| // Sunday's trick: if we're going to jump, we might |
| // as well jump to line up the character *after* the |
| // current window. |
| STRINGLIB_CHAR first_outside = window[len_needle]; |
| SHIFT_TYPE shift = table[first_outside & TABLE_MASK]; |
| if (shift == NOT_FOUND) { |
| LOG("\"%c\" not found. Skipping entirely.\n", |
| first_outside); |
| window += len_needle + 1; |
| } |
| else { |
| LOG("Shifting to line up \"%c\".\n", first_outside); |
| window += shift; |
| } |
| goto windowloop; |
| } |
| for (Py_ssize_t i = cut + 1; i < len_needle; i++) { |
| if (needle[i] != window[i]) { |
| LOG("Right half does not match. Advance by %d.\n", |
| i - cut + 1); |
| window += i - cut + 1; |
| goto windowloop; |
| } |
| } |
| for (Py_ssize_t i = 0; i < cut; i++) { |
| if (needle[i] != window[i]) { |
| LOG("Left half does not match. Advance by period %d.\n", |
| period); |
| window += period; |
| goto windowloop; |
| } |
| } |
| LOG("Left half matches. Returning %d.\n", window - haystack); |
| return window - haystack; |
| } |
| } |
| LOG("Not found. Returning -1.\n"); |
| return -1; |
| } |
| |
| Py_LOCAL_INLINE(Py_ssize_t) |
| STRINGLIB(_two_way_find)(const STRINGLIB_CHAR *haystack, |
| Py_ssize_t len_haystack, |
| const STRINGLIB_CHAR *needle, |
| Py_ssize_t len_needle) |
| { |
| LOG("###### Finding \"%s\" in \"%s\".\n", needle, haystack); |
| STRINGLIB(prework) p; |
| STRINGLIB(_preprocess)(needle, len_needle, &p); |
| return STRINGLIB(_two_way)(haystack, len_haystack, &p); |
| } |
| |
| Py_LOCAL_INLINE(Py_ssize_t) |
| STRINGLIB(_two_way_count)(const STRINGLIB_CHAR *haystack, |
| Py_ssize_t len_haystack, |
| const STRINGLIB_CHAR *needle, |
| Py_ssize_t len_needle, |
| Py_ssize_t maxcount) |
| { |
| LOG("###### Counting \"%s\" in \"%s\".\n", needle, haystack); |
| STRINGLIB(prework) p; |
| STRINGLIB(_preprocess)(needle, len_needle, &p); |
| Py_ssize_t index = 0, count = 0; |
| while (1) { |
| Py_ssize_t result; |
| result = STRINGLIB(_two_way)(haystack + index, |
| len_haystack - index, &p); |
| if (result == -1) { |
| return count; |
| } |
| count++; |
| if (count == maxcount) { |
| return maxcount; |
| } |
| index += result + len_needle; |
| } |
| return count; |
| } |
| |
| #undef SHIFT_TYPE |
| #undef NOT_FOUND |
| #undef SHIFT_OVERFLOW |
| #undef TABLE_SIZE_BITS |
| #undef TABLE_SIZE |
| #undef TABLE_MASK |
| |
| #undef LOG |
| #undef LOG_STRING |
| |
| Py_LOCAL_INLINE(Py_ssize_t) |
| FASTSEARCH(const STRINGLIB_CHAR* s, Py_ssize_t n, |
| const STRINGLIB_CHAR* p, Py_ssize_t m, |
| Py_ssize_t maxcount, int mode) |
| { |
| unsigned long mask; |
| Py_ssize_t skip, count = 0; |
| Py_ssize_t i, j, mlast, w; |
| |
| w = n - m; |
| |
| if (w < 0 || (mode == FAST_COUNT && maxcount == 0)) |
| return -1; |
| |
| /* look for special cases */ |
| if (m <= 1) { |
| if (m <= 0) |
| return -1; |
| /* use special case for 1-character strings */ |
| if (mode == FAST_SEARCH) |
| return STRINGLIB(find_char)(s, n, p[0]); |
| else if (mode == FAST_RSEARCH) |
| return STRINGLIB(rfind_char)(s, n, p[0]); |
| else { /* FAST_COUNT */ |
| for (i = 0; i < n; i++) |
| if (s[i] == p[0]) { |
| count++; |
| if (count == maxcount) |
| return maxcount; |
| } |
| return count; |
| } |
| } |
| |
| mlast = m - 1; |
| skip = mlast; |
| mask = 0; |
| |
| if (mode != FAST_RSEARCH) { |
| if (m >= 100 && w >= 2000 && w / m >= 5) { |
| /* For larger problems where the needle isn't a huge |
| percentage of the size of the haystack, the relatively |
| expensive O(m) startup cost of the two-way algorithm |
| will surely pay off. */ |
| if (mode == FAST_SEARCH) { |
| return STRINGLIB(_two_way_find)(s, n, p, m); |
| } |
| else { |
| return STRINGLIB(_two_way_count)(s, n, p, m, maxcount); |
| } |
| } |
| const STRINGLIB_CHAR *ss = s + m - 1; |
| const STRINGLIB_CHAR *pp = p + m - 1; |
| |
| /* create compressed boyer-moore delta 1 table */ |
| |
| /* process pattern[:-1] */ |
| for (i = 0; i < mlast; i++) { |
| STRINGLIB_BLOOM_ADD(mask, p[i]); |
| if (p[i] == p[mlast]) { |
| skip = mlast - i - 1; |
| } |
| } |
| /* process pattern[-1] outside the loop */ |
| STRINGLIB_BLOOM_ADD(mask, p[mlast]); |
| |
| if (m >= 100 && w >= 8000) { |
| /* To ensure that we have good worst-case behavior, |
| here's an adaptive version of the algorithm, where if |
| we match O(m) characters without any matches of the |
| entire needle, then we predict that the startup cost of |
| the two-way algorithm will probably be worth it. */ |
| Py_ssize_t hits = 0; |
| for (i = 0; i <= w; i++) { |
| if (ss[i] == pp[0]) { |
| /* candidate match */ |
| for (j = 0; j < mlast; j++) { |
| if (s[i+j] != p[j]) { |
| break; |
| } |
| } |
| if (j == mlast) { |
| /* got a match! */ |
| if (mode != FAST_COUNT) { |
| return i; |
| } |
| count++; |
| if (count == maxcount) { |
| return maxcount; |
| } |
| i = i + mlast; |
| continue; |
| } |
| /* miss: check if next character is part of pattern */ |
| if (!STRINGLIB_BLOOM(mask, ss[i+1])) { |
| i = i + m; |
| } |
| else { |
| i = i + skip; |
| } |
| hits += j + 1; |
| if (hits >= m / 4 && i < w - 1000) { |
| /* We've done O(m) fruitless comparisons |
| anyway, so spend the O(m) cost on the |
| setup for the two-way algorithm. */ |
| Py_ssize_t res; |
| if (mode == FAST_COUNT) { |
| res = STRINGLIB(_two_way_count)( |
| s+i, n-i, p, m, maxcount-count); |
| return count + res; |
| } |
| else { |
| res = STRINGLIB(_two_way_find)(s+i, n-i, p, m); |
| if (res == -1) { |
| return -1; |
| } |
| return i + res; |
| } |
| } |
| } |
| else { |
| /* skip: check if next character is part of pattern */ |
| if (!STRINGLIB_BLOOM(mask, ss[i+1])) { |
| i = i + m; |
| } |
| } |
| } |
| if (mode != FAST_COUNT) { |
| return -1; |
| } |
| return count; |
| } |
| /* The standard, non-adaptive version of the algorithm. */ |
| for (i = 0; i <= w; i++) { |
| /* note: using mlast in the skip path slows things down on x86 */ |
| if (ss[i] == pp[0]) { |
| /* candidate match */ |
| for (j = 0; j < mlast; j++) { |
| if (s[i+j] != p[j]) { |
| break; |
| } |
| } |
| if (j == mlast) { |
| /* got a match! */ |
| if (mode != FAST_COUNT) { |
| return i; |
| } |
| count++; |
| if (count == maxcount) { |
| return maxcount; |
| } |
| i = i + mlast; |
| continue; |
| } |
| /* miss: check if next character is part of pattern */ |
| if (!STRINGLIB_BLOOM(mask, ss[i+1])) { |
| i = i + m; |
| } |
| else { |
| i = i + skip; |
| } |
| } |
| else { |
| /* skip: check if next character is part of pattern */ |
| if (!STRINGLIB_BLOOM(mask, ss[i+1])) { |
| i = i + m; |
| } |
| } |
| } |
| } |
| else { /* FAST_RSEARCH */ |
| |
| /* create compressed boyer-moore delta 1 table */ |
| |
| /* process pattern[0] outside the loop */ |
| STRINGLIB_BLOOM_ADD(mask, p[0]); |
| /* process pattern[:0:-1] */ |
| for (i = mlast; i > 0; i--) { |
| STRINGLIB_BLOOM_ADD(mask, p[i]); |
| if (p[i] == p[0]) { |
| skip = i - 1; |
| } |
| } |
| |
| for (i = w; i >= 0; i--) { |
| if (s[i] == p[0]) { |
| /* candidate match */ |
| for (j = mlast; j > 0; j--) { |
| if (s[i+j] != p[j]) { |
| break; |
| } |
| } |
| if (j == 0) { |
| /* got a match! */ |
| return i; |
| } |
| /* miss: check if previous character is part of pattern */ |
| if (i > 0 && !STRINGLIB_BLOOM(mask, s[i-1])) { |
| i = i - m; |
| } |
| else { |
| i = i - skip; |
| } |
| } |
| else { |
| /* skip: check if previous character is part of pattern */ |
| if (i > 0 && !STRINGLIB_BLOOM(mask, s[i-1])) { |
| i = i - m; |
| } |
| } |
| } |
| } |
| |
| if (mode != FAST_COUNT) |
| return -1; |
| return count; |
| } |
| |
