/* SPDX-License-Identifier: LGPL-2.1+ */ #include #include #include #include #include #include "alloc-util.h" #include "escape.h" #include "extract-word.h" #include "fileio.h" #include "memory-util.h" #include "nulstr-util.h" #include "sort-util.h" #include "string-util.h" #include "strv.h" char *strv_find(char * const *l, const char *name) { char * const *i; assert(name); STRV_FOREACH(i, l) if (streq(*i, name)) return *i; return NULL; } char *strv_find_case(char * const *l, const char *name) { char * const *i; assert(name); STRV_FOREACH(i, l) if (strcaseeq(*i, name)) return *i; return NULL; } char *strv_find_prefix(char * const *l, const char *name) { char * const *i; assert(name); STRV_FOREACH(i, l) if (startswith(*i, name)) return *i; return NULL; } char *strv_find_startswith(char * const *l, const char *name) { char * const *i, *e; assert(name); /* Like strv_find_prefix, but actually returns only the * suffix, not the whole item */ STRV_FOREACH(i, l) { e = startswith(*i, name); if (e) return e; } return NULL; } char **strv_free(char **l) { char **k; if (!l) return NULL; for (k = l; *k; k++) free(*k); return mfree(l); } char **strv_free_erase(char **l) { char **i; STRV_FOREACH(i, l) erase_and_freep(i); return mfree(l); } char **strv_copy(char * const *l) { char **r, **k; k = r = new(char*, strv_length(l) + 1); if (!r) return NULL; if (l) for (; *l; k++, l++) { *k = strdup(*l); if (!*k) { strv_free(r); return NULL; } } *k = NULL; return r; } size_t strv_length(char * const *l) { size_t n = 0; if (!l) return 0; for (; *l; l++) n++; return n; } char **strv_new_ap(const char *x, va_list ap) { const char *s; _cleanup_strv_free_ char **a = NULL; size_t n = 0, i = 0; va_list aq; /* As a special trick we ignore all listed strings that equal * STRV_IGNORE. This is supposed to be used with the * STRV_IFNOTNULL() macro to include possibly NULL strings in * the string list. */ if (x) { n = x == STRV_IGNORE ? 0 : 1; va_copy(aq, ap); while ((s = va_arg(aq, const char*))) { if (s == STRV_IGNORE) continue; n++; } va_end(aq); } a = new(char*, n+1); if (!a) return NULL; if (x) { if (x != STRV_IGNORE) { a[i] = strdup(x); if (!a[i]) return NULL; i++; } while ((s = va_arg(ap, const char*))) { if (s == STRV_IGNORE) continue; a[i] = strdup(s); if (!a[i]) return NULL; i++; } } a[i] = NULL; return TAKE_PTR(a); } char **strv_new_internal(const char *x, ...) { char **r; va_list ap; va_start(ap, x); r = strv_new_ap(x, ap); va_end(ap); return r; } int strv_extend_strv(char ***a, char * const *b, bool filter_duplicates) { char * const *s, **t; size_t p, q, i = 0, j; assert(a); if (strv_isempty(b)) return 0; p = strv_length(*a); q = strv_length(b); if (p >= SIZE_MAX - q) return -ENOMEM; t = reallocarray(*a, GREEDY_ALLOC_ROUND_UP(p + q + 1), sizeof(char *)); if (!t) return -ENOMEM; t[p] = NULL; *a = t; STRV_FOREACH(s, b) { if (filter_duplicates && strv_contains(t, *s)) continue; t[p+i] = strdup(*s); if (!t[p+i]) goto rollback; i++; t[p+i] = NULL; } assert(i <= q); return (int) i; rollback: for (j = 0; j < i; j++) free(t[p + j]); t[p] = NULL; return -ENOMEM; } int strv_extend_strv_concat(char ***a, char * const *b, const char *suffix) { char * const *s; int r; STRV_FOREACH(s, b) { char *v; v = strjoin(*s, suffix); if (!v) return -ENOMEM; r = strv_push(a, v); if (r < 0) { free(v); return r; } } return 0; } char **strv_split_newlines(const char *s) { char **l; size_t n; assert(s); /* Special version of strv_split() that splits on newlines and * suppresses an empty string at the end */ l = strv_split(s, NEWLINE); if (!l) return NULL; n = strv_length(l); if (n <= 0) return l; if (isempty(l[n - 1])) l[n - 1] = mfree(l[n - 1]); return l; } int strv_split_full(char ***t, const char *s, const char *separators, ExtractFlags flags) { _cleanup_strv_free_ char **l = NULL; size_t n = 0, allocated = 0; int r; assert(t); assert(s); for (;;) { _cleanup_free_ char *word = NULL; r = extract_first_word(&s, &word, separators, flags); if (r < 0) return r; if (r == 0) break; if (!GREEDY_REALLOC(l, allocated, n + 2)) return -ENOMEM; l[n++] = TAKE_PTR(word); l[n] = NULL; } if (!l) { l = new0(char*, 1); if (!l) return -ENOMEM; } *t = TAKE_PTR(l); return (int) n; } int strv_split_colon_pairs(char ***t, const char *s) { _cleanup_strv_free_ char **l = NULL; size_t n = 0, allocated = 0; int r; assert(t); assert(s); for (;;) { _cleanup_free_ char *first = NULL, *second = NULL, *tuple = NULL, *second_or_empty = NULL; r = extract_first_word(&s, &tuple, NULL, EXTRACT_UNQUOTE|EXTRACT_RETAIN_ESCAPE); if (r < 0) return r; if (r == 0) break; const char *p = tuple; r = extract_many_words(&p, ":", EXTRACT_CUNESCAPE|EXTRACT_UNESCAPE_SEPARATORS, &first, &second, NULL); if (r < 0) return r; if (r == 0) continue; /* Enforce that at most 2 colon-separated words are contained in each group */ if (!isempty(p)) return -EINVAL; second_or_empty = strdup(strempty(second)); if (!second_or_empty) return -ENOMEM; if (!GREEDY_REALLOC(l, allocated, n + 3)) return -ENOMEM; l[n++] = TAKE_PTR(first); l[n++] = TAKE_PTR(second_or_empty); l[n] = NULL; } if (!l) { l = new0(char*, 1); if (!l) return -ENOMEM; } *t = TAKE_PTR(l); return (int) n; } char *strv_join_full(char * const *l, const char *separator, const char *prefix, bool unescape_separators) { char * const *s; char *r, *e; size_t n, k, m; if (!separator) separator = " "; k = strlen(separator); m = strlen_ptr(prefix); if (unescape_separators) /* If there separator is multi-char, we won't know how to escape it. */ assert(k == 1); n = 0; STRV_FOREACH(s, l) { if (s != l) n += k; bool needs_escaping = unescape_separators && strchr(*s, separator[0]); n += m + strlen(*s) * (1 + needs_escaping); } r = new(char, n+1); if (!r) return NULL; e = r; STRV_FOREACH(s, l) { if (s != l) e = stpcpy(e, separator); if (prefix) e = stpcpy(e, prefix); bool needs_escaping = unescape_separators && strchr(*s, separator[0]); if (needs_escaping) for (size_t i = 0; (*s)[i]; i++) { if ((*s)[i] == separator[0]) *(e++) = '\\'; *(e++) = (*s)[i]; } else e = stpcpy(e, *s); } *e = 0; return r; } int strv_push(char ***l, char *value) { char **c; size_t n; if (!value) return 0; n = strv_length(*l); /* Check for overflow */ if (n > SIZE_MAX-2) return -ENOMEM; c = reallocarray(*l, GREEDY_ALLOC_ROUND_UP(n + 2), sizeof(char*)); if (!c) return -ENOMEM; c[n] = value; c[n+1] = NULL; *l = c; return 0; } int strv_push_pair(char ***l, char *a, char *b) { char **c; size_t n; if (!a && !b) return 0; n = strv_length(*l); /* Check for overflow */ if (n > SIZE_MAX-3) return -ENOMEM; /* increase and check for overflow */ c = reallocarray(*l, GREEDY_ALLOC_ROUND_UP(n + !!a + !!b + 1), sizeof(char*)); if (!c) return -ENOMEM; if (a) c[n++] = a; if (b) c[n++] = b; c[n] = NULL; *l = c; return 0; } int strv_insert(char ***l, size_t position, char *value) { char **c; size_t n, m, i; if (!value) return 0; n = strv_length(*l); position = MIN(position, n); /* increase and check for overflow */ m = n + 2; if (m < n) return -ENOMEM; c = new(char*, m); if (!c) return -ENOMEM; for (i = 0; i < position; i++) c[i] = (*l)[i]; c[position] = value; for (i = position; i < n; i++) c[i+1] = (*l)[i]; c[n+1] = NULL; free(*l); *l = c; return 0; } int strv_consume(char ***l, char *value) { int r; r = strv_push(l, value); if (r < 0) free(value); return r; } int strv_consume_pair(char ***l, char *a, char *b) { int r; r = strv_push_pair(l, a, b); if (r < 0) { free(a); free(b); } return r; } int strv_consume_prepend(char ***l, char *value) { int r; r = strv_push_prepend(l, value); if (r < 0) free(value); return r; } int strv_prepend(char ***l, const char *value) { char *v; if (!value) return 0; v = strdup(value); if (!v) return -ENOMEM; return strv_consume_prepend(l, v); } int strv_extend(char ***l, const char *value) { char *v; if (!value) return 0; v = strdup(value); if (!v) return -ENOMEM; return strv_consume(l, v); } int strv_extend_front(char ***l, const char *value) { size_t n, m; char *v, **c; assert(l); /* Like strv_extend(), but prepends rather than appends the new entry */ if (!value) return 0; n = strv_length(*l); /* Increase and overflow check. */ m = n + 2; if (m < n) return -ENOMEM; v = strdup(value); if (!v) return -ENOMEM; c = reallocarray(*l, m, sizeof(char*)); if (!c) { free(v); return -ENOMEM; } memmove(c+1, c, n * sizeof(char*)); c[0] = v; c[n+1] = NULL; *l = c; return 0; } char **strv_uniq(char **l) { char **i; /* Drops duplicate entries. The first identical string will be * kept, the others dropped */ STRV_FOREACH(i, l) strv_remove(i+1, *i); return l; } bool strv_is_uniq(char * const *l) { char * const *i; STRV_FOREACH(i, l) if (strv_find(i+1, *i)) return false; return true; } char **strv_remove(char **l, const char *s) { char **f, **t; if (!l) return NULL; assert(s); /* Drops every occurrence of s in the string list, edits * in-place. */ for (f = t = l; *f; f++) if (streq(*f, s)) free(*f); else *(t++) = *f; *t = NULL; return l; } char **strv_parse_nulstr(const char *s, size_t l) { /* l is the length of the input data, which will be split at NULs into * elements of the resulting strv. Hence, the number of items in the resulting strv * will be equal to one plus the number of NUL bytes in the l bytes starting at s, * unless s[l-1] is NUL, in which case the final empty string is not stored in * the resulting strv, and length is equal to the number of NUL bytes. * * Note that contrary to a normal nulstr which cannot contain empty strings, because * the input data is terminated by any two consequent NUL bytes, this parser accepts * empty strings in s. */ const char *p; size_t c = 0, i = 0; char **v; assert(s || l <= 0); if (l <= 0) return new0(char*, 1); for (p = s; p < s + l; p++) if (*p == 0) c++; if (s[l-1] != 0) c++; v = new0(char*, c+1); if (!v) return NULL; p = s; while (p < s + l) { const char *e; e = memchr(p, 0, s + l - p); v[i] = strndup(p, e ? e - p : s + l - p); if (!v[i]) { strv_free(v); return NULL; } i++; if (!e) break; p = e + 1; } assert(i == c); return v; } char **strv_split_nulstr(const char *s) { const char *i; char **r = NULL; NULSTR_FOREACH(i, s) if (strv_extend(&r, i) < 0) { strv_free(r); return NULL; } if (!r) return strv_new(NULL); return r; } int strv_make_nulstr(char * const *l, char **ret, size_t *ret_size) { /* A valid nulstr with two NULs at the end will be created, but * q will be the length without the two trailing NULs. Thus the output * string is a valid nulstr and can be iterated over using NULSTR_FOREACH, * and can also be parsed by strv_parse_nulstr as long as the length * is provided separately. */ size_t n_allocated = 0, n = 0; _cleanup_free_ char *m = NULL; char * const *i; assert(ret); assert(ret_size); STRV_FOREACH(i, l) { size_t z; z = strlen(*i); if (!GREEDY_REALLOC(m, n_allocated, n + z + 2)) return -ENOMEM; memcpy(m + n, *i, z + 1); n += z + 1; } if (!m) { m = new0(char, 1); if (!m) return -ENOMEM; n = 1; } else /* make sure there is a second extra NUL at the end of resulting nulstr */ m[n] = '\0'; assert(n > 0); *ret = m; *ret_size = n - 1; m = NULL; return 0; } bool strv_overlap(char * const *a, char * const *b) { char * const *i; STRV_FOREACH(i, a) if (strv_contains(b, *i)) return true; return false; } static int str_compare(char * const *a, char * const *b) { return strcmp(*a, *b); } char **strv_sort(char **l) { typesafe_qsort(l, strv_length(l), str_compare); return l; } int strv_compare(char * const *a, char * const *b) { int r; if (strv_isempty(a)) { if (strv_isempty(b)) return 0; else return -1; } if (strv_isempty(b)) return 1; for ( ; *a || *b; ++a, ++b) { r = strcmp_ptr(*a, *b); if (r != 0) return r; } return 0; } void strv_print(char * const *l) { char * const *s; STRV_FOREACH(s, l) puts(*s); } int strv_extendf(char ***l, const char *format, ...) { va_list ap; char *x; int r; va_start(ap, format); r = vasprintf(&x, format, ap); va_end(ap); if (r < 0) return -ENOMEM; return strv_consume(l, x); } char **strv_reverse(char **l) { size_t n, i; n = strv_length(l); if (n <= 1) return l; for (i = 0; i < n / 2; i++) SWAP_TWO(l[i], l[n-1-i]); return l; } char **strv_shell_escape(char **l, const char *bad) { char **s; /* Escapes every character in every string in l that is in bad, * edits in-place, does not roll-back on error. */ STRV_FOREACH(s, l) { char *v; v = shell_escape(*s, bad); if (!v) return NULL; free(*s); *s = v; } return l; } bool strv_fnmatch_full(char* const* patterns, const char *s, int flags, size_t *matched_pos) { for (size_t i = 0; patterns && patterns[i]; i++) if (fnmatch(patterns[i], s, flags) == 0) { if (matched_pos) *matched_pos = i; return true; } return false; } char ***strv_free_free(char ***l) { char ***i; if (!l) return NULL; for (i = l; *i; i++) strv_free(*i); return mfree(l); } char **strv_skip(char **l, size_t n) { while (n > 0) { if (strv_isempty(l)) return l; l++, n--; } return l; } int strv_extend_n(char ***l, const char *value, size_t n) { size_t i, j, k; char **nl; assert(l); if (!value) return 0; if (n == 0) return 0; /* Adds the value n times to l */ k = strv_length(*l); if (n >= SIZE_MAX - k) return -ENOMEM; nl = reallocarray(*l, GREEDY_ALLOC_ROUND_UP(k + n + 1), sizeof(char *)); if (!nl) return -ENOMEM; *l = nl; for (i = k; i < k + n; i++) { nl[i] = strdup(value); if (!nl[i]) goto rollback; } nl[i] = NULL; return 0; rollback: for (j = k; j < i; j++) free(nl[j]); nl[k] = NULL; return -ENOMEM; } int fputstrv(FILE *f, char * const *l, const char *separator, bool *space) { bool b = false; char * const *s; int r; /* Like fputs(), but for strv, and with a less stupid argument order */ if (!space) space = &b; STRV_FOREACH(s, l) { r = fputs_with_space(f, *s, separator, space); if (r < 0) return r; } return 0; } static int string_strv_hashmap_put_internal(Hashmap *h, const char *key, const char *value) { char **l; int r; l = hashmap_get(h, key); if (l) { /* A list for this key already exists, let's append to it if it is not listed yet */ if (strv_contains(l, value)) return 0; r = strv_extend(&l, value); if (r < 0) return r; assert_se(hashmap_update(h, key, l) >= 0); } else { /* No list for this key exists yet, create one */ _cleanup_strv_free_ char **l2 = NULL; _cleanup_free_ char *t = NULL; t = strdup(key); if (!t) return -ENOMEM; r = strv_extend(&l2, value); if (r < 0) return r; r = hashmap_put(h, t, l2); if (r < 0) return r; TAKE_PTR(t); TAKE_PTR(l2); } return 1; } int _string_strv_hashmap_put(Hashmap **h, const char *key, const char *value HASHMAP_DEBUG_PARAMS) { int r; r = _hashmap_ensure_allocated(h, &string_strv_hash_ops HASHMAP_DEBUG_PASS_ARGS); if (r < 0) return r; return string_strv_hashmap_put_internal(*h, key, value); } int _string_strv_ordered_hashmap_put(OrderedHashmap **h, const char *key, const char *value HASHMAP_DEBUG_PARAMS) { int r; r = _ordered_hashmap_ensure_allocated(h, &string_strv_hash_ops HASHMAP_DEBUG_PASS_ARGS); if (r < 0) return r; return string_strv_hashmap_put_internal(PLAIN_HASHMAP(*h), key, value); } DEFINE_HASH_OPS_FULL(string_strv_hash_ops, char, string_hash_func, string_compare_func, free, char*, strv_free);