/* Copyright (c) 2003-2004, Roger Dingledine * Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson. * Copyright (c) 2007-2013, The Tor Project, Inc. */ /* See LICENSE for licensing information */ #ifndef TOR_CONTAINER_H #define TOR_CONTAINER_H #include "util.h" /** A resizeable list of pointers, with associated helpful functionality. * * The members of this struct are exposed only so that macros and inlines can * use them; all access to smartlist internals should go through the functions * and macros defined here. **/ typedef struct smartlist_t { /** @{ */ /** list has enough capacity to store exactly capacity elements * before it needs to be resized. Only the first num_used (\<= * capacity) elements point to valid data. */ void **list; int num_used; int capacity; /** @} */ } smartlist_t; smartlist_t *smartlist_new(void); void smartlist_free(smartlist_t *sl); void smartlist_clear(smartlist_t *sl); void smartlist_add(smartlist_t *sl, void *element); void smartlist_add_all(smartlist_t *sl, const smartlist_t *s2); void smartlist_remove(smartlist_t *sl, const void *element); void *smartlist_pop_last(smartlist_t *sl); void smartlist_reverse(smartlist_t *sl); void smartlist_string_remove(smartlist_t *sl, const char *element); int smartlist_contains(const smartlist_t *sl, const void *element); int smartlist_contains_string(const smartlist_t *sl, const char *element); int smartlist_string_pos(const smartlist_t *, const char *elt); int smartlist_contains_string_case(const smartlist_t *sl, const char *element); int smartlist_contains_int_as_string(const smartlist_t *sl, int num); int smartlist_strings_eq(const smartlist_t *sl1, const smartlist_t *sl2); int smartlist_contains_digest(const smartlist_t *sl, const char *element); int smartlist_overlap(const smartlist_t *sl1, const smartlist_t *sl2); void smartlist_intersect(smartlist_t *sl1, const smartlist_t *sl2); void smartlist_subtract(smartlist_t *sl1, const smartlist_t *sl2); /* smartlist_choose() is defined in crypto.[ch] */ #ifdef DEBUG_SMARTLIST /** Return the number of items in sl. */ static INLINE int smartlist_len(const smartlist_t *sl); static INLINE int smartlist_len(const smartlist_t *sl) { tor_assert(sl); return (sl)->num_used; } /** Return the idxth element of sl. */ static INLINE void *smartlist_get(const smartlist_t *sl, int idx); static INLINE void *smartlist_get(const smartlist_t *sl, int idx) { tor_assert(sl); tor_assert(idx>=0); tor_assert(sl->num_used > idx); return sl->list[idx]; } static INLINE void smartlist_set(smartlist_t *sl, int idx, void *val) { tor_assert(sl); tor_assert(idx>=0); tor_assert(sl->num_used > idx); sl->list[idx] = val; } #else #define smartlist_len(sl) ((sl)->num_used) #define smartlist_get(sl, idx) ((sl)->list[idx]) #define smartlist_set(sl, idx, val) ((sl)->list[idx] = (val)) #endif /** Exchange the elements at indices idx1 and idx2 of the * smartlist sl. */ static INLINE void smartlist_swap(smartlist_t *sl, int idx1, int idx2) { if (idx1 != idx2) { void *elt = smartlist_get(sl, idx1); smartlist_set(sl, idx1, smartlist_get(sl, idx2)); smartlist_set(sl, idx2, elt); } } void smartlist_del(smartlist_t *sl, int idx); void smartlist_del_keeporder(smartlist_t *sl, int idx); void smartlist_insert(smartlist_t *sl, int idx, void *val); void smartlist_sort(smartlist_t *sl, int (*compare)(const void **a, const void **b)); void *smartlist_get_most_frequent(const smartlist_t *sl, int (*compare)(const void **a, const void **b)); void smartlist_uniq(smartlist_t *sl, int (*compare)(const void **a, const void **b), void (*free_fn)(void *elt)); void smartlist_sort_strings(smartlist_t *sl); void smartlist_sort_digests(smartlist_t *sl); void smartlist_sort_digests256(smartlist_t *sl); char *smartlist_get_most_frequent_string(smartlist_t *sl); char *smartlist_get_most_frequent_digest256(smartlist_t *sl); void smartlist_uniq_strings(smartlist_t *sl); void smartlist_uniq_digests(smartlist_t *sl); void smartlist_uniq_digests256(smartlist_t *sl); void *smartlist_bsearch(smartlist_t *sl, const void *key, int (*compare)(const void *key, const void **member)); int smartlist_bsearch_idx(const smartlist_t *sl, const void *key, int (*compare)(const void *key, const void **member), int *found_out); void smartlist_pqueue_add(smartlist_t *sl, int (*compare)(const void *a, const void *b), int idx_field_offset, void *item); void *smartlist_pqueue_pop(smartlist_t *sl, int (*compare)(const void *a, const void *b), int idx_field_offset); void smartlist_pqueue_remove(smartlist_t *sl, int (*compare)(const void *a, const void *b), int idx_field_offset, void *item); void smartlist_pqueue_assert_ok(smartlist_t *sl, int (*compare)(const void *a, const void *b), int idx_field_offset); #define SPLIT_SKIP_SPACE 0x01 #define SPLIT_IGNORE_BLANK 0x02 #define SPLIT_STRIP_SPACE 0x04 int smartlist_split_string(smartlist_t *sl, const char *str, const char *sep, int flags, int max); char *smartlist_join_strings(smartlist_t *sl, const char *join, int terminate, size_t *len_out) ATTR_MALLOC; char *smartlist_join_strings2(smartlist_t *sl, const char *join, size_t join_len, int terminate, size_t *len_out) ATTR_MALLOC; /** Iterate over the items in a smartlist sl, in order. For each item, * assign it to a new local variable of type type named var, and * execute the statements inside the loop body. Inside the loop, the loop * index can be accessed as var_sl_idx and the length of the list can * be accessed as var_sl_len. * * NOTE: Do not change the length of the list while the loop is in progress, * unless you adjust the _sl_len variable correspondingly. See second example * below. * * Example use: *
* smartlist_t *list = smartlist_split("A:B:C", ":", 0, 0); * SMARTLIST_FOREACH_BEGIN(list, char *, cp) { * printf("%d: %s\n", cp_sl_idx, cp); * tor_free(cp); * } SMARTLIST_FOREACH_END(cp); * smartlist_free(list); ** * Example use (advanced): *
* SMARTLIST_FOREACH_BEGIN(list, char *, cp) { * if (!strcmp(cp, "junk")) { * tor_free(cp); * SMARTLIST_DEL_CURRENT(list, cp); * } * } SMARTLIST_FOREACH_END(cp); **/ /* Note: these macros use token pasting, and reach into smartlist internals. * This can make them a little daunting. Here's the approximate unpacking of * the above examples, for entertainment value: * *
* smartlist_t *list = smartlist_split("A:B:C", ":", 0, 0); * { * int cp_sl_idx, cp_sl_len = smartlist_len(list); * char *cp; * for (cp_sl_idx = 0; cp_sl_idx < cp_sl_len; ++cp_sl_idx) { * cp = smartlist_get(list, cp_sl_idx); * printf("%d: %s\n", cp_sl_idx, cp); * tor_free(cp); * } * } * smartlist_free(list); ** *
* { * int cp_sl_idx, cp_sl_len = smartlist_len(list); * char *cp; * for (cp_sl_idx = 0; cp_sl_idx < cp_sl_len; ++cp_sl_idx) { * cp = smartlist_get(list, cp_sl_idx); * if (!strcmp(cp, "junk")) { * tor_free(cp); * smartlist_del(list, cp_sl_idx); * --cp_sl_idx; * --cp_sl_len; * } * } * } **/ #define SMARTLIST_FOREACH_BEGIN(sl, type, var) \ STMT_BEGIN \ int var ## _sl_idx, var ## _sl_len=(sl)->num_used; \ type var; \ for (var ## _sl_idx = 0; var ## _sl_idx < var ## _sl_len; \ ++var ## _sl_idx) { \ var = (sl)->list[var ## _sl_idx]; #define SMARTLIST_FOREACH_END(var) \ var = NULL; \ } STMT_END /** * An alias for SMARTLIST_FOREACH_BEGIN and SMARTLIST_FOREACH_END, using * cmd as the loop body. This wrapper is here for convenience with * very short loops. * * By convention, we do not use this for loops which nest, or for loops over * 10 lines or so. Use SMARTLIST_FOREACH_{BEGIN,END} for those. */ #define SMARTLIST_FOREACH(sl, type, var, cmd) \ SMARTLIST_FOREACH_BEGIN(sl,type,var) { \ cmd; \ } SMARTLIST_FOREACH_END(var) /** Helper: While in a SMARTLIST_FOREACH loop over the list sl indexed * with the variable var, remove the current element in a way that * won't confuse the loop. */ #define SMARTLIST_DEL_CURRENT(sl, var) \ STMT_BEGIN \ smartlist_del(sl, var ## _sl_idx); \ --var ## _sl_idx; \ --var ## _sl_len; \ STMT_END /** Helper: While in a SMARTLIST_FOREACH loop over the list sl indexed * with the variable var, replace the current element with val. * Does not deallocate the current value of var. */ #define SMARTLIST_REPLACE_CURRENT(sl, var, val) \ STMT_BEGIN \ smartlist_set(sl, var ## _sl_idx, val); \ STMT_END /* Helper: Given two lists of items, possibly of different types, such that * both lists are sorted on some common field (as determined by a comparison * expression cmpexpr), and such that one list (sl1) has no * duplicates on the common field, loop through the lists in lockstep, and * execute unmatched_var2 on items in var2 that do not appear in * var1. * * WARNING: It isn't safe to add remove elements from either list while the * loop is in progress. * * Example use: * SMARTLIST_FOREACH_JOIN(routerstatus_list, routerstatus_t *, rs, * routerinfo_list, routerinfo_t *, ri, * tor_memcmp(rs->identity_digest, ri->identity_digest, 20), * log_info(LD_GENERAL,"No match for %s", ri->nickname)) { * log_info(LD_GENERAL, "%s matches routerstatus %p", ri->nickname, rs); * } SMARTLIST_FOREACH_JOIN_END(rs, ri); **/ /* The example above unpacks (approximately) to: * int rs_sl_idx = 0, rs_sl_len = smartlist_len(routerstatus_list); * int ri_sl_idx, ri_sl_len = smartlist_len(routerinfo_list); * int rs_ri_cmp; * routerstatus_t *rs; * routerinfo_t *ri; * for (; ri_sl_idx < ri_sl_len; ++ri_sl_idx) { * ri = smartlist_get(routerinfo_list, ri_sl_idx); * while (rs_sl_idx < rs_sl_len) { * rs = smartlist_get(routerstatus_list, rs_sl_idx); * rs_ri_cmp = tor_memcmp(rs->identity_digest, ri->identity_digest, 20); * if (rs_ri_cmp > 0) { * break; * } else if (rs_ri_cmp == 0) { * goto matched_ri; * } else { * ++rs_sl_idx; * } * } * log_info(LD_GENERAL,"No match for %s", ri->nickname); * continue; * matched_ri: { * log_info(LD_GENERAL,"%s matches with routerstatus %p",ri->nickname,rs); * } * } */ #define SMARTLIST_FOREACH_JOIN(sl1, type1, var1, sl2, type2, var2, \ cmpexpr, unmatched_var2) \ STMT_BEGIN \ int var1 ## _sl_idx = 0, var1 ## _sl_len=(sl1)->num_used; \ int var2 ## _sl_idx = 0, var2 ## _sl_len=(sl2)->num_used; \ int var1 ## _ ## var2 ## _cmp; \ type1 var1; \ type2 var2; \ for (; var2##_sl_idx < var2##_sl_len; ++var2##_sl_idx) { \ var2 = (sl2)->list[var2##_sl_idx]; \ while (var1##_sl_idx < var1##_sl_len) { \ var1 = (sl1)->list[var1##_sl_idx]; \ var1##_##var2##_cmp = (cmpexpr); \ if (var1##_##var2##_cmp > 0) { \ break; \ } else if (var1##_##var2##_cmp == 0) { \ goto matched_##var2; \ } else { \ ++var1##_sl_idx; \ } \ } \ /* Ran out of v1, or no match for var2. */ \ unmatched_var2; \ continue; \ matched_##var2: ; \ #define SMARTLIST_FOREACH_JOIN_END(var1, var2) \ } \ STMT_END #define DECLARE_MAP_FNS(maptype, keytype, prefix) \ typedef struct maptype maptype; \ typedef struct prefix##entry_t *prefix##iter_t; \ maptype* prefix##new(void); \ void* prefix##set(maptype *map, keytype key, void *val); \ void* prefix##get(const maptype *map, keytype key); \ void* prefix##remove(maptype *map, keytype key); \ void prefix##free(maptype *map, void (*free_val)(void*)); \ int prefix##isempty(const maptype *map); \ int prefix##size(const maptype *map); \ prefix##iter_t *prefix##iter_init(maptype *map); \ prefix##iter_t *prefix##iter_next(maptype *map, prefix##iter_t *iter); \ prefix##iter_t *prefix##iter_next_rmv(maptype *map, prefix##iter_t *iter); \ void prefix##iter_get(prefix##iter_t *iter, keytype *keyp, void **valp); \ int prefix##iter_done(prefix##iter_t *iter); \ void prefix##assert_ok(const maptype *map) /* Map from const char * to void *. Implemented with a hash table. */ DECLARE_MAP_FNS(strmap_t, const char *, strmap_); /* Map from const char[DIGEST_LEN] to void *. Implemented with a hash table. */ DECLARE_MAP_FNS(digestmap_t, const char *, digestmap_); #undef DECLARE_MAP_FNS /** Iterates over the key-value pairs in a map map in order. * prefix is as for DECLARE_MAP_FNS (i.e., strmap_ or digestmap_). * The map's keys and values are of type keytype and valtype respectively; * each iteration assigns them to keyvar and valvar. * * Example use: * MAP_FOREACH(digestmap_, m, const char *, k, routerinfo_t *, r) { * // use k and r * } MAP_FOREACH_END. */ /* Unpacks to, approximately: * { * digestmap_iter_t *k_iter; * for (k_iter = digestmap_iter_init(m); !digestmap_iter_done(k_iter); * k_iter = digestmap_iter_next(m, k_iter)) { * const char *k; * void *r_voidp; * routerinfo_t *r; * digestmap_iter_get(k_iter, &k, &r_voidp); * r = r_voidp; * // use k and r * } * } */ #define MAP_FOREACH(prefix, map, keytype, keyvar, valtype, valvar) \ STMT_BEGIN \ prefix##iter_t *keyvar##_iter; \ for (keyvar##_iter = prefix##iter_init(map); \ !prefix##iter_done(keyvar##_iter); \ keyvar##_iter = prefix##iter_next(map, keyvar##_iter)) { \ keytype keyvar; \ void *valvar##_voidp; \ valtype valvar; \ prefix##iter_get(keyvar##_iter, &keyvar, &valvar##_voidp); \ valvar = valvar##_voidp; /** As MAP_FOREACH, except allows members to be removed from the map * during the iteration via MAP_DEL_CURRENT. Example use: * * Example use: * MAP_FOREACH(digestmap_, m, const char *, k, routerinfo_t *, r) { * if (is_very_old(r)) * MAP_DEL_CURRENT(k); * } MAP_FOREACH_END. **/ /* Unpacks to, approximately: * { * digestmap_iter_t *k_iter; * int k_del=0; * for (k_iter = digestmap_iter_init(m); !digestmap_iter_done(k_iter); * k_iter = k_del ? digestmap_iter_next(m, k_iter) * : digestmap_iter_next_rmv(m, k_iter)) { * const char *k; * void *r_voidp; * routerinfo_t *r; * k_del=0; * digestmap_iter_get(k_iter, &k, &r_voidp); * r = r_voidp; * if (is_very_old(r)) { * k_del = 1; * } * } * } */ #define MAP_FOREACH_MODIFY(prefix, map, keytype, keyvar, valtype, valvar) \ STMT_BEGIN \ prefix##iter_t *keyvar##_iter; \ int keyvar##_del=0; \ for (keyvar##_iter = prefix##iter_init(map); \ !prefix##iter_done(keyvar##_iter); \ keyvar##_iter = keyvar##_del ? \ prefix##iter_next_rmv(map, keyvar##_iter) : \ prefix##iter_next(map, keyvar##_iter)) { \ keytype keyvar; \ void *valvar##_voidp; \ valtype valvar; \ keyvar##_del=0; \ prefix##iter_get(keyvar##_iter, &keyvar, &valvar##_voidp); \ valvar = valvar##_voidp; /** Used with MAP_FOREACH_MODIFY to remove the currently-iterated-upon * member of the map. */ #define MAP_DEL_CURRENT(keyvar) \ STMT_BEGIN \ keyvar##_del = 1; \ STMT_END /** Used to end a MAP_FOREACH() block. */ #define MAP_FOREACH_END } STMT_END ; /** As MAP_FOREACH, but does not require declaration of prefix or keytype. * Example use: * DIGESTMAP_FOREACH(m, k, routerinfo_t *, r) { * // use k and r * } DIGESTMAP_FOREACH_END. */ #define DIGESTMAP_FOREACH(map, keyvar, valtype, valvar) \ MAP_FOREACH(digestmap_, map, const char *, keyvar, valtype, valvar) /** As MAP_FOREACH_MODIFY, but does not require declaration of prefix or * keytype. * Example use: * DIGESTMAP_FOREACH_MODIFY(m, k, routerinfo_t *, r) { * if (is_very_old(r)) * MAP_DEL_CURRENT(k); * } DIGESTMAP_FOREACH_END. */ #define DIGESTMAP_FOREACH_MODIFY(map, keyvar, valtype, valvar) \ MAP_FOREACH_MODIFY(digestmap_, map, const char *, keyvar, valtype, valvar) /** Used to end a DIGESTMAP_FOREACH() block. */ #define DIGESTMAP_FOREACH_END MAP_FOREACH_END #define STRMAP_FOREACH(map, keyvar, valtype, valvar) \ MAP_FOREACH(strmap_, map, const char *, keyvar, valtype, valvar) #define STRMAP_FOREACH_MODIFY(map, keyvar, valtype, valvar) \ MAP_FOREACH_MODIFY(strmap_, map, const char *, keyvar, valtype, valvar) #define STRMAP_FOREACH_END MAP_FOREACH_END void* strmap_set_lc(strmap_t *map, const char *key, void *val); void* strmap_get_lc(const strmap_t *map, const char *key); void* strmap_remove_lc(strmap_t *map, const char *key); #define DECLARE_TYPED_DIGESTMAP_FNS(prefix, maptype, valtype) \ typedef struct maptype maptype; \ typedef struct prefix##iter_t prefix##iter_t; \ ATTR_UNUSED static INLINE maptype* \ prefix##new(void) \ { \ return (maptype*)digestmap_new(); \ } \ ATTR_UNUSED static INLINE digestmap_t* \ prefix##to_digestmap(maptype *map) \ { \ return (digestmap_t*)map; \ } \ ATTR_UNUSED static INLINE valtype* \ prefix##get(maptype *map, const char *key) \ { \ return (valtype*)digestmap_get((digestmap_t*)map, key); \ } \ ATTR_UNUSED static INLINE valtype* \ prefix##set(maptype *map, const char *key, valtype *val) \ { \ return (valtype*)digestmap_set((digestmap_t*)map, key, val); \ } \ ATTR_UNUSED static INLINE valtype* \ prefix##remove(maptype *map, const char *key) \ { \ return (valtype*)digestmap_remove((digestmap_t*)map, key); \ } \ ATTR_UNUSED static INLINE void \ prefix##free(maptype *map, void (*free_val)(void*)) \ { \ digestmap_free((digestmap_t*)map, free_val); \ } \ ATTR_UNUSED static INLINE int \ prefix##isempty(maptype *map) \ { \ return digestmap_isempty((digestmap_t*)map); \ } \ ATTR_UNUSED static INLINE int \ prefix##size(maptype *map) \ { \ return digestmap_size((digestmap_t*)map); \ } \ ATTR_UNUSED static INLINE \ prefix##iter_t *prefix##iter_init(maptype *map) \ { \ return (prefix##iter_t*) digestmap_iter_init((digestmap_t*)map); \ } \ ATTR_UNUSED static INLINE \ prefix##iter_t *prefix##iter_next(maptype *map, prefix##iter_t *iter) \ { \ return (prefix##iter_t*) digestmap_iter_next( \ (digestmap_t*)map, (digestmap_iter_t*)iter); \ } \ ATTR_UNUSED static INLINE prefix##iter_t* \ prefix##iter_next_rmv(maptype *map, prefix##iter_t *iter) \ { \ return (prefix##iter_t*) digestmap_iter_next_rmv( \ (digestmap_t*)map, (digestmap_iter_t*)iter); \ } \ ATTR_UNUSED static INLINE void \ prefix##iter_get(prefix##iter_t *iter, \ const char **keyp, \ valtype **valp) \ { \ void *v; \ digestmap_iter_get((digestmap_iter_t*) iter, keyp, &v); \ *valp = v; \ } \ ATTR_UNUSED static INLINE int \ prefix##iter_done(prefix##iter_t *iter) \ { \ return digestmap_iter_done((digestmap_iter_t*)iter); \ } #if SIZEOF_INT == 4 #define BITARRAY_SHIFT 5 #elif SIZEOF_INT == 8 #define BITARRAY_SHIFT 6 #else #error "int is neither 4 nor 8 bytes. I can't deal with that." #endif #define BITARRAY_MASK ((1u<