/* Copyright (c) 2008-2012 Red Hat, Inc. This file is part of GlusterFS. This file is licensed to you under your choice of the GNU Lesser General Public License, version 3 or any later version (LGPLv3 or later), or the GNU General Public License, version 2 (GPLv2), in all cases as published by the Free Software Foundation. */ #include #include #include #include #include #include #include #include "glusterfs/dict.h" #define XXH_INLINE_ALL #include "xxhash.h" #include "glusterfs/compat.h" #include "glusterfs/compat-errno.h" #include "glusterfs/byte-order.h" #include "glusterfs/statedump.h" #include "glusterfs/libglusterfs-messages.h" struct dict_cmp { dict_t *dict; gf_boolean_t (*value_ignore)(char *k); }; #define VALIDATE_DATA_AND_LOG(data, type, key, ret_val) \ do { \ if (!data || !data->data) { \ gf_msg_callingfn("dict", GF_LOG_DEBUG, EINVAL, LG_MSG_INVALID_ARG, \ "data is NULL"); \ return ret_val; \ } \ /* Not of the asked type, or old version */ \ if ((data->data_type != type) && \ (data->data_type != GF_DATA_TYPE_STR_OLD)) { \ gf_msg_callingfn("dict", GF_LOG_DEBUG, EINVAL, LG_MSG_INVALID_ARG, \ "key %s, %s type asked, has %s type", key, \ data_type_name[type], \ data_type_name[data->data_type]); \ } \ } while (0) static data_t * get_new_data() { data_t *data = mem_get(THIS->ctx->dict_data_pool); if (!data) return NULL; GF_ATOMIC_INIT(data->refcount, 0); data->is_static = _gf_false; return data; } static dict_t * get_new_dict_full(int size_hint) { dict_t *dict = mem_get0(THIS->ctx->dict_pool); if (!dict) { return NULL; } dict->hash_size = size_hint; if (size_hint == 1) { /* * This is the only case we ever see currently. If we ever * need to support resizing the hash table, the resize function * will have to take into account the possibility that * "members" is not separately allocated (i.e. don't just call * realloc() blindly. */ dict->members = &dict->members_internal; } else { /* * We actually need to allocate space for size_hint *pointers* * but we actually allocate space for one *structure*. Since * a data_pair_t consists of five pointers, we're wasting four * pointers' worth for N=1, and will overrun what we allocated * for N>5. If anybody ever starts using size_hint, we'll need * to fix this. */ GF_ASSERT(size_hint <= (sizeof(data_pair_t) / sizeof(data_pair_t *))); dict->members = mem_get0(THIS->ctx->dict_pair_pool); if (!dict->members) { mem_put(dict); return NULL; } } LOCK_INIT(&dict->lock); return dict; } dict_t * dict_new(void) { dict_t *dict = get_new_dict_full(1); if (dict) dict_ref(dict); return dict; } int32_t is_data_equal(data_t *one, data_t *two) { struct iatt *iatt1, *iatt2; struct mdata_iatt *mdata_iatt1, *mdata_iatt2; if (!one || !two || !one->data || !two->data) { gf_msg_callingfn("dict", GF_LOG_ERROR, EINVAL, LG_MSG_INVALID_ARG, "input arguments are provided " "with value data_t as NULL"); return -1; } if (one == two) return 1; if (one->data == two->data) return 1; if (one->data_type != two->data_type) { return 0; } if (one->data_type == GF_DATA_TYPE_IATT) { if ((one->len < sizeof(struct iatt)) || (two->len < sizeof(struct iatt))) { return 0; } iatt1 = (struct iatt *)one->data; iatt2 = (struct iatt *)two->data; /* Two iatt structs are considered equal if main fields are * equal, even if times differ. * TODO: maybe when ctime if fully operational we could * enforce time matching. */ if (iatt1->ia_ino != iatt2->ia_ino) { return 0; } if (iatt1->ia_type != iatt2->ia_type) { return 0; } if ((iatt1->ia_type == IA_IFBLK) || (iatt1->ia_type == IA_IFCHR)) { if (iatt1->ia_rdev != iatt2->ia_rdev) { return 0; } } if (gf_uuid_compare(iatt1->ia_gfid, iatt2->ia_gfid) != 0) { return 0; } /* TODO: ia_uid, ia_gid, ia_prot and ia_size can be changed * with some commands. Here we don't have enough * information to decide if they should match or not. */ /* if ((iatt1->ia_uid != iatt2->ia_uid) || (iatt1->ia_gid != iatt2->ia_gid) || (st_mode_from_ia(iatt1->ia_prot, iatt1->ia_type) != st_mode_from_ia(iatt2->ia_prot, iatt2->ia_type))) { return 0; } if (iatt1->ia_type == IA_IFREG) { if (iatt1->ia_size != iatt2->ia_size) { return 0; } } */ return 1; } if (one->data_type == GF_DATA_TYPE_MDATA) { if ((one->len < sizeof(struct mdata_iatt)) || (two->len < sizeof(struct mdata_iatt))) { return 0; } mdata_iatt1 = (struct mdata_iatt *)one->data; mdata_iatt2 = (struct mdata_iatt *)two->data; if (mdata_iatt1->ia_atime != mdata_iatt2->ia_atime || mdata_iatt1->ia_mtime != mdata_iatt2->ia_mtime || mdata_iatt1->ia_ctime != mdata_iatt2->ia_ctime || mdata_iatt1->ia_atime_nsec != mdata_iatt2->ia_atime_nsec || mdata_iatt1->ia_mtime_nsec != mdata_iatt2->ia_mtime_nsec || mdata_iatt1->ia_ctime_nsec != mdata_iatt2->ia_ctime_nsec) { return 0; } return 1; } if (one->len != two->len) return 0; if (memcmp(one->data, two->data, one->len) == 0) return 1; return 0; } static int key_value_cmp(dict_t *one, char *key1, data_t *value1, void *data) { struct dict_cmp *cmp = data; dict_t *two = cmp->dict; data_t *value2 = dict_get(two, key1); if (value2) { if (cmp->value_ignore && cmp->value_ignore(key1)) return 0; if (is_data_equal(value1, value2) == 1) return 0; } if (value2 == NULL) { gf_msg_debug(THIS->name, 0, "'%s' found only on one dict", key1); } else { gf_msg_debug(THIS->name, 0, "'%s' is different in two dicts " "(%u, %u)", key1, value1->len, value2->len); } return -1; } /* If both dicts are NULL then equal. If one of the dicts is NULL but the * other has only ignorable keys then also they are equal. If both dicts are * non-null then check if for each non-ignorable key, values are same or * not. value_ignore function is used to skip comparing values for the keys * which must be present in both the dictionaries but the value could be * different. */ gf_boolean_t are_dicts_equal(dict_t *one, dict_t *two, gf_boolean_t (*match)(dict_t *d, char *k, data_t *v, void *data), gf_boolean_t (*value_ignore)(char *k)) { int num_matches1 = 0; int num_matches2 = 0; struct dict_cmp cmp = {0}; if (one == two) return _gf_true; if (!match) match = dict_match_everything; if ((one == NULL) || (two == NULL)) { num_matches1 = dict_foreach_match(one ? one : two, match, NULL, dict_null_foreach_fn, NULL); goto done; } cmp.dict = two; cmp.value_ignore = value_ignore; num_matches1 = dict_foreach_match(one, match, NULL, key_value_cmp, &cmp); if (num_matches1 == -1) return _gf_false; if ((num_matches1 == one->count) && (one->count == two->count)) return _gf_true; num_matches2 = dict_foreach_match(two, match, NULL, dict_null_foreach_fn, NULL); done: /* If the number of matches is same in 'two' then for all the * valid-keys that exist in 'one' the value matched and no extra valid * keys exist in 'two' alone. Otherwise there exists at least one extra * valid-key in 'two' which doesn't exist in 'one' */ if (num_matches1 == num_matches2) return _gf_true; return _gf_false; } void data_destroy(data_t *data) { if (data) { if (!data->is_static) GF_FREE(data->data); data->len = 0xbabababa; mem_put(data); } } data_t * data_copy(data_t *old) { if (!old) { gf_msg_callingfn("dict", GF_LOG_WARNING, 0, LG_MSG_NULL_PTR, "old is NULL"); return NULL; } data_t *newdata = mem_get0(THIS->ctx->dict_data_pool); if (!newdata) { return NULL; } newdata->len = old->len; if (old->data) { newdata->data = gf_memdup(old->data, old->len); if (!newdata->data) goto err_out; } newdata->data_type = old->data_type; return newdata; err_out: mem_put(newdata); return NULL; } /* Always need to be called under lock * Always this and key variables are not null - * checked by callers. */ static data_pair_t * dict_lookup_common(dict_t *this, char *key, uint32_t hash) { int hashval = 0; data_pair_t *pair; /* If the divisor is 1, the modulo is always 0, * in such case avoid hash calculation. */ if (this->hash_size != 1) hashval = hash % this->hash_size; for (pair = this->members[hashval]; pair != NULL; pair = pair->hash_next) { if (pair->key && (hash == pair->key_hash) && !strcmp(pair->key, key)) return pair; } return NULL; } int32_t dict_lookup(dict_t *this, char *key, data_t **data) { if (!this || !key || !data) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "!this || !key || " "!data"); return -1; } data_pair_t *tmp = NULL; uint32_t hash = (uint32_t)XXH64(key, strlen(key), 0); LOCK(&this->lock); { tmp = dict_lookup_common(this, key, hash); } UNLOCK(&this->lock); if (!tmp) return -1; *data = tmp->value; return 0; } static int32_t dict_set_lk(dict_t *this, char *key, const int key_len, data_t *value, const uint32_t hash, gf_boolean_t replace) { int hashval = 0; data_pair_t *pair; int key_free = 0; uint32_t key_hash; int keylen; if (!key) { keylen = gf_asprintf(&key, "ref:%p", value); if (-1 == keylen) { return -1; } key_free = 1; key_hash = (uint32_t)XXH64(key, keylen, 0); } else { keylen = key_len; key_hash = hash; } /* Search for a existing key if 'replace' is asked for */ if (replace) { pair = dict_lookup_common(this, key, key_hash); if (pair) { data_t *unref_data = pair->value; pair->value = data_ref(value); data_unref(unref_data); if (key_free) GF_FREE(key); /* Indicates duplicate key */ return 0; } } if (this->free_pair_in_use) { pair = mem_get(THIS->ctx->dict_pair_pool); if (!pair) { if (key_free) GF_FREE(key); return -1; } } else { pair = &this->free_pair; this->free_pair_in_use = _gf_true; } if (key_free) { /* It's ours. Use it. */ pair->key = key; key_free = 0; } else { pair->key = (char *)GF_MALLOC(keylen + 1, gf_common_mt_char); if (!pair->key) { if (pair == &this->free_pair) { this->free_pair_in_use = _gf_false; } else { mem_put(pair); } return -1; } strcpy(pair->key, key); } pair->key_hash = key_hash; pair->value = data_ref(value); /* If the divisor is 1, the modulo is always 0, * in such case avoid hash calculation. */ if (this->hash_size != 1) { hashval = (key_hash % this->hash_size); } pair->hash_next = this->members[hashval]; this->members[hashval] = pair; pair->next = this->members_list; pair->prev = NULL; if (this->members_list) this->members_list->prev = pair; this->members_list = pair; this->count++; if (key_free) GF_FREE(key); if (this->max_count < this->count) this->max_count = this->count; return 0; } int32_t dict_set(dict_t *this, char *key, data_t *value) { if (key) return dict_setn(this, key, strlen(key), value); else return dict_setn(this, NULL, 0, value); } int32_t dict_setn(dict_t *this, char *key, const int keylen, data_t *value) { int32_t ret; uint32_t key_hash = 0; if (!this || !value) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "!this || !value for " "key=%s", key); return -1; } if (key) { key_hash = (uint32_t)XXH64(key, keylen, 0); } LOCK(&this->lock); ret = dict_set_lk(this, key, keylen, value, key_hash, 1); UNLOCK(&this->lock); return ret; } int32_t dict_add(dict_t *this, char *key, data_t *value) { if (key) return dict_addn(this, key, strlen(key), value); else return dict_addn(this, NULL, 0, value); } int32_t dict_addn(dict_t *this, char *key, const int keylen, data_t *value) { int32_t ret; uint32_t key_hash = 0; if (!this || !value) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "!this || !value for key=%s", key); return -1; } if (key) { key_hash = (uint32_t)XXH64(key, keylen, 0); } LOCK(&this->lock); ret = dict_set_lk(this, key, keylen, value, key_hash, 0); UNLOCK(&this->lock); return ret; } data_t * dict_get(dict_t *this, char *key) { if (!key) { gf_msg_callingfn("dict", GF_LOG_DEBUG, EINVAL, LG_MSG_INVALID_ARG, "!key"); return NULL; } return dict_getn(this, key, strlen(key)); } data_t * dict_getn(dict_t *this, char *key, const int keylen) { data_pair_t *pair; uint32_t hash; if (!this || !key) { gf_msg_callingfn("dict", GF_LOG_DEBUG, EINVAL, LG_MSG_INVALID_ARG, "!this || key=%s", (key) ? key : "()"); return NULL; } hash = (uint32_t)XXH64(key, keylen, 0); LOCK(&this->lock); { pair = dict_lookup_common(this, key, hash); } UNLOCK(&this->lock); if (pair) return pair->value; return NULL; } int dict_key_count(dict_t *this) { int ret = -1; if (!this) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "dict passed is NULL"); return ret; } LOCK(&this->lock); { ret = this->count; } UNLOCK(&this->lock); return ret; } void dict_del(dict_t *this, char *key) { if (!key) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "!key"); return; } return dict_deln(this, key, strlen(key)); } void dict_deln(dict_t *this, char *key, const int keylen) { int hashval = 0; uint32_t hash; if (!this || !key) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "!this || key=%s", (key) ? key : "()"); return; } hash = (uint32_t)XXH64(key, keylen, 0); LOCK(&this->lock); /* If the divisor is 1, the modulo is always 0, * in such case avoid hash calculation. */ if (this->hash_size != 1) hashval = hash % this->hash_size; data_pair_t *pair = this->members[hashval]; data_pair_t *prev = NULL; while (pair) { if ((hash == pair->key_hash) && strcmp(pair->key, key) == 0) { if (prev) prev->hash_next = pair->hash_next; else this->members[hashval] = pair->hash_next; data_unref(pair->value); if (pair->prev) pair->prev->next = pair->next; else this->members_list = pair->next; if (pair->next) pair->next->prev = pair->prev; GF_FREE(pair->key); if (pair == &this->free_pair) { this->free_pair_in_use = _gf_false; } else { mem_put(pair); } this->count--; break; } prev = pair; pair = pair->hash_next; } UNLOCK(&this->lock); return; } void dict_destroy(dict_t *this) { if (!this) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "dict is NULL"); return; } data_pair_t *pair = this->members_list; data_pair_t *prev = this->members_list; glusterfs_ctx_t *ctx = NULL; uint64_t current_max = 0; uint32_t total_pairs = 0; LOCK_DESTROY(&this->lock); while (prev) { pair = pair->next; data_unref(prev->value); GF_FREE(prev->key); if (prev != &this->free_pair) { mem_put(prev); } total_pairs++; prev = pair; } if (this->members != &this->members_internal) { mem_put(this->members); } GF_FREE(this->extra_free); free(this->extra_stdfree); /* update 'ctx->stats.dict.details' using max_count */ ctx = THIS->ctx; /* NOTE: below logic is not totaly race proof */ /* thread0 and thread1 gets current_max as 10 */ /* thread0 has 'this->max_count as 11 */ /* thread1 has 'this->max_count as 20 */ /* thread1 goes ahead and sets the max_dict_pairs to 20 */ /* thread0 then goes and sets it to 11 */ /* As it is for information purpose only, no functionality will be broken by this, but a point to consider about ATOMIC macros. */ current_max = GF_ATOMIC_GET(ctx->stats.max_dict_pairs); if (current_max < this->max_count) GF_ATOMIC_INIT(ctx->stats.max_dict_pairs, this->max_count); GF_ATOMIC_ADD(ctx->stats.total_pairs_used, total_pairs); GF_ATOMIC_INC(ctx->stats.total_dicts_used); mem_put(this); return; } void dict_unref(dict_t *this) { uint64_t ref = 0; if (!this) { gf_msg_callingfn("dict", GF_LOG_DEBUG, EINVAL, LG_MSG_INVALID_ARG, "dict is NULL"); return; } ref = GF_ATOMIC_DEC(this->refcount); if (!ref) dict_destroy(this); } dict_t * dict_ref(dict_t *this) { if (!this) { gf_msg_callingfn("dict", GF_LOG_DEBUG, EINVAL, LG_MSG_INVALID_ARG, "dict is NULL"); return NULL; } GF_ATOMIC_INC(this->refcount); return this; } void data_unref(data_t *this) { uint64_t ref; if (!this) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "data is NULL"); return; } ref = GF_ATOMIC_DEC(this->refcount); if (!ref) data_destroy(this); } data_t * data_ref(data_t *this) { if (!this) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "data is NULL"); return NULL; } GF_ATOMIC_INC(this->refcount); return this; } data_t * int_to_data(int64_t value) { data_t *data = get_new_data(); if (!data) { return NULL; } data->len = gf_asprintf(&data->data, "%" PRId64, value); if (-1 == data->len) { gf_msg_debug("dict", 0, "asprintf failed"); return NULL; } data->len++; /* account for terminating NULL */ data->data_type = GF_DATA_TYPE_INT; return data; } data_t * data_from_int64(int64_t value) { data_t *data = get_new_data(); if (!data) { return NULL; } data->len = gf_asprintf(&data->data, "%" PRId64, value); if (-1 == data->len) { gf_msg_debug("dict", 0, "asprintf failed"); return NULL; } data->len++; /* account for terminating NULL */ data->data_type = GF_DATA_TYPE_INT; return data; } data_t * data_from_int32(int32_t value) { data_t *data = get_new_data(); if (!data) { return NULL; } data->len = gf_asprintf(&data->data, "%" PRId32, value); if (-1 == data->len) { gf_msg_debug("dict", 0, "asprintf failed"); return NULL; } data->len++; /* account for terminating NULL */ data->data_type = GF_DATA_TYPE_INT; return data; } data_t * data_from_int16(int16_t value) { data_t *data = get_new_data(); if (!data) { return NULL; } data->len = gf_asprintf(&data->data, "%" PRId16, value); if (-1 == data->len) { gf_msg_debug("dict", 0, "asprintf failed"); return NULL; } data->len++; /* account for terminating NULL */ data->data_type = GF_DATA_TYPE_INT; return data; } data_t * data_from_int8(int8_t value) { data_t *data = get_new_data(); if (!data) { return NULL; } data->len = gf_asprintf(&data->data, "%d", value); if (-1 == data->len) { gf_msg_debug("dict", 0, "asprintf failed"); return NULL; } data->len++; /* account for terminating NULL */ data->data_type = GF_DATA_TYPE_INT; return data; } data_t * data_from_uint64(uint64_t value) { data_t *data = get_new_data(); if (!data) { return NULL; } data->len = gf_asprintf(&data->data, "%" PRIu64, value); if (-1 == data->len) { gf_msg_debug("dict", 0, "asprintf failed"); return NULL; } data->len++; /* account for terminating NULL */ data->data_type = GF_DATA_TYPE_UINT; return data; } data_t * data_from_double(double value) { data_t *data = get_new_data(); if (!data) { return NULL; } data->len = gf_asprintf(&data->data, "%f", value); if (data->len == -1) { return NULL; } data->len++; /* account for terminating NULL */ data->data_type = GF_DATA_TYPE_DOUBLE; return data; } data_t * data_from_uint32(uint32_t value) { data_t *data = get_new_data(); if (!data) { return NULL; } data->len = gf_asprintf(&data->data, "%" PRIu32, value); if (-1 == data->len) { gf_msg_debug("dict", 0, "asprintf failed"); return NULL; } data->len++; /* account for terminating NULL */ data->data_type = GF_DATA_TYPE_UINT; return data; } data_t * data_from_uint16(uint16_t value) { data_t *data = get_new_data(); if (!data) { return NULL; } data->len = gf_asprintf(&data->data, "%" PRIu16, value); if (-1 == data->len) { return NULL; } data->len++; /* account for terminating NULL */ data->data_type = GF_DATA_TYPE_UINT; return data; } static data_t * data_from_ptr_common(void *value, gf_boolean_t is_static) { /* it is valid to set 0/NULL as a value, no need to check *value */ data_t *data = get_new_data(); if (!data) { return NULL; } data->data = value; data->len = 0; data->is_static = is_static; data->data_type = GF_DATA_TYPE_PTR; return data; } data_t * str_to_data(char *value) { if (!value) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "value is NULL"); return NULL; } return strn_to_data(value, strlen(value)); } data_t * strn_to_data(char *value, const int vallen) { if (!value) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "value is NULL"); return NULL; } data_t *data = get_new_data(); if (!data) { return NULL; } data->len = vallen + 1; data->data_type = GF_DATA_TYPE_STR; data->data = value; data->is_static = _gf_true; return data; } static data_t * data_from_dynstr(char *value) { if (!value) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "value is NULL"); return NULL; } data_t *data = get_new_data(); if (!data) return NULL; data->len = strlen(value) + 1; data->data = value; data->data_type = GF_DATA_TYPE_STR; return data; } data_t * data_from_dynptr(void *value, int32_t len) { data_t *data = get_new_data(); if (!data) return NULL; data->len = len; data->data = value; data->data_type = GF_DATA_TYPE_PTR; return data; } data_t * bin_to_data(void *value, int32_t len) { if (!value) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "value is NULL"); return NULL; } data_t *data = get_new_data(); if (!data) return NULL; data->is_static = _gf_true; data->len = len; data->data = value; return data; } static char *data_type_name[GF_DATA_TYPE_MAX] = { [GF_DATA_TYPE_UNKNOWN] = "unknown", [GF_DATA_TYPE_STR_OLD] = "string-old-version", [GF_DATA_TYPE_INT] = "integer", [GF_DATA_TYPE_UINT] = "unsigned integer", [GF_DATA_TYPE_DOUBLE] = "float", [GF_DATA_TYPE_STR] = "string", [GF_DATA_TYPE_PTR] = "pointer", [GF_DATA_TYPE_GFUUID] = "gf-uuid", [GF_DATA_TYPE_IATT] = "iatt", [GF_DATA_TYPE_MDATA] = "mdata", }; int64_t data_to_int64(data_t *data) { VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_INT, "null", -1); return (int64_t)strtoull(data->data, NULL, 0); } int32_t data_to_int32(data_t *data) { VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_INT, "null", -1); return strtoul(data->data, NULL, 0); } int16_t data_to_int16(data_t *data) { VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_INT, "null", -1); int16_t value = 0; errno = 0; value = strtol(data->data, NULL, 0); if ((value > SHRT_MAX) || (value < SHRT_MIN)) { errno = ERANGE; gf_msg_callingfn("dict", GF_LOG_WARNING, errno, LG_MSG_DATA_CONVERSION_ERROR, "Error in data" " conversion: detected overflow"); return -1; } return (int16_t)value; } int8_t data_to_int8(data_t *data) { VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_INT, "null", -1); int8_t value = 0; errno = 0; value = strtol(data->data, NULL, 0); if ((value > SCHAR_MAX) || (value < SCHAR_MIN)) { errno = ERANGE; gf_msg_callingfn("dict", GF_LOG_WARNING, errno, LG_MSG_DATA_CONVERSION_ERROR, "Error in data" " conversion: detected overflow"); return -1; } return (int8_t)value; } uint64_t data_to_uint64(data_t *data) { VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_UINT, "null", -1); return strtoll(data->data, NULL, 0); } uint32_t data_to_uint32(data_t *data) { VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_UINT, "null", -1); return strtol(data->data, NULL, 0); } uint16_t data_to_uint16(data_t *data) { VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_UINT, "null", -1); uint16_t value = 0; errno = 0; value = strtol(data->data, NULL, 0); if ((USHRT_MAX - value) < 0) { errno = ERANGE; gf_msg_callingfn("dict", GF_LOG_WARNING, errno, LG_MSG_DATA_CONVERSION_ERROR, "Error in data conversion: " "overflow detected"); return -1; } return (uint16_t)value; } uint8_t data_to_uint8(data_t *data) { VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_UINT, "null", -1); errno = 0; uint32_t value = strtol(data->data, NULL, 0); if ((UCHAR_MAX - (uint8_t)value) < 0) { errno = ERANGE; gf_msg_callingfn("dict", GF_LOG_WARNING, errno, LG_MSG_DATA_CONVERSION_ERROR, "data " "conversion overflow detected"); return -1; } return (uint8_t)value; } char * data_to_str(data_t *data) { VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_STR, "null", NULL); return data->data; } void * data_to_ptr(data_t *data) { VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_PTR, "null", NULL); return data->data; } void * data_to_bin(data_t *data) { VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_PTR, "null", NULL); return data->data; } struct iatt * data_to_iatt(data_t *data, char *key) { VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_IATT, key, NULL); /* We only check for smaller size. If it's bigger we simply ignore * the extra data. This way it's easy to do changes in the future that * pass more data but are backward compatible (if the initial contents * of the struct are maintained, of course). */ if (data->len < sizeof(struct iatt)) { gf_msg("glusterfs", GF_LOG_ERROR, ENOBUFS, LG_MSG_UNDERSIZED_BUF, "data value for '%s' is smaller than expected", key); return NULL; } return (struct iatt *)data->data; } int dict_null_foreach_fn(dict_t *d, char *k, data_t *v, void *tmp) { return 0; } int dict_remove_foreach_fn(dict_t *d, char *k, data_t *v, void *_tmp) { dict_del(d, k); return 0; } gf_boolean_t dict_match_everything(dict_t *d, char *k, data_t *v, void *data) { return _gf_true; } int dict_foreach(dict_t *dict, int (*fn)(dict_t *this, char *key, data_t *value, void *data), void *data) { int ret = dict_foreach_match(dict, dict_match_everything, NULL, fn, data); if (ret > 0) ret = 0; return ret; } /* return values: -1 = failure, 0 = no matches found, +n = n number of matches */ int dict_foreach_match(dict_t *dict, gf_boolean_t (*match)(dict_t *this, char *key, data_t *value, void *mdata), void *match_data, int (*action)(dict_t *this, char *key, data_t *value, void *adata), void *action_data) { if (!dict || !match || !action) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "dict|match|action is " "NULL"); return -1; } int ret = -1; int count = 0; data_pair_t *pairs = dict->members_list; data_pair_t *next = NULL; while (pairs) { next = pairs->next; if (match(dict, pairs->key, pairs->value, match_data)) { ret = action(dict, pairs->key, pairs->value, action_data); if (ret < 0) return ret; count++; } pairs = next; } return count; } static gf_boolean_t dict_fnmatch(dict_t *d, char *k, data_t *val, void *match_data) { return (fnmatch(match_data, k, 0) == 0); } /* return values: -1 = failure, 0 = no matches found, +n = n number of matches */ int dict_foreach_fnmatch(dict_t *dict, char *pattern, int (*fn)(dict_t *this, char *key, data_t *value, void *data), void *data) { return dict_foreach_match(dict, dict_fnmatch, pattern, fn, data); } /** * dict_keys_join - pack the keys of the dictionary in a buffer. * * @value : buffer in which the keys will be packed (can be NULL) * @size : size of the buffer which is sent (can be 0, in which case buffer * is not packed but only length is returned) * @dict : dictionary of which all the keys will be packed * @filter_fn : keys matched in filter_fn() is counted. * * @return : @length of string after joining keys. * */ int dict_keys_join(void *value, int size, dict_t *dict, int (*filter_fn)(char *k)) { int len = 0; data_pair_t *pairs = dict->members_list; data_pair_t *next = NULL; while (pairs) { next = pairs->next; if (filter_fn && filter_fn(pairs->key)) { pairs = next; continue; } if (value && (size > len)) strncpy(value + len, pairs->key, size - len); len += (strlen(pairs->key) + 1); pairs = next; } return len; } static int dict_copy_one(dict_t *unused, char *key, data_t *value, void *newdict) { return dict_set((dict_t *)newdict, key, (value)); } dict_t * dict_copy(dict_t *dict, dict_t *new) { if (!dict) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "dict is NULL"); return NULL; } if (!new) new = get_new_dict_full(dict->hash_size); dict_foreach(dict, dict_copy_one, new); return new; } int dict_reset(dict_t *dict) { int32_t ret = -1; if (!dict) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "dict is NULL"); goto out; } dict_foreach(dict, dict_remove_foreach_fn, NULL); ret = 0; out: return ret; } dict_t * dict_copy_with_ref(dict_t *dict, dict_t *new) { dict_t *local_new = NULL; GF_VALIDATE_OR_GOTO("dict", dict, fail); if (new == NULL) { local_new = dict_new(); GF_VALIDATE_OR_GOTO("dict", local_new, fail); new = local_new; } dict_foreach(dict, dict_copy_one, new); fail: return new; } /* * !!!!!!! CLEANED UP CODE !!!!!!! */ /** * Common cleaned up interface: * * Return value: 0 success * -val error, val = errno */ int dict_get_with_ref(dict_t *this, char *key, data_t **data) { if (!key) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "!key"); return -EINVAL; } return dict_get_with_refn(this, key, strlen(key), data); } int dict_get_with_refn(dict_t *this, char *key, const int keylen, data_t **data) { data_pair_t *pair = NULL; int ret = -ENOENT; uint32_t hash; if (!this || !key || !data) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "dict OR key (%s) is NULL", key); ret = -EINVAL; goto err; } hash = (uint32_t)XXH64(key, keylen, 0); LOCK(&this->lock); { pair = dict_lookup_common(this, key, hash); if (pair) { ret = 0; *data = data_ref(pair->value); } } UNLOCK(&this->lock); err: return ret; } static int data_to_int8_ptr(data_t *data, int8_t *val) { int ret = 0; errno = 0; *val = strtol(data->data, NULL, 0); if (errno != 0) ret = -errno; return ret; } static int data_to_int16_ptr(data_t *data, int16_t *val) { int ret = 0; errno = 0; *val = strtol(data->data, NULL, 0); if (errno != 0) ret = -errno; return ret; } static int data_to_int32_ptr(data_t *data, int32_t *val) { int ret = 0; errno = 0; *val = strtol(data->data, NULL, 0); if (errno != 0) ret = -errno; return ret; } static int data_to_int64_ptr(data_t *data, int64_t *val) { int ret = 0; errno = 0; *val = strtoll(data->data, NULL, 0); if (errno != 0) ret = -errno; return ret; } static int data_to_uint16_ptr(data_t *data, uint16_t *val) { int ret = 0; errno = 0; *val = strtoul(data->data, NULL, 0); if (errno != 0) ret = -errno; return ret; } static int data_to_uint32_ptr(data_t *data, uint32_t *val) { int ret = 0; errno = 0; *val = strtoul(data->data, NULL, 0); if (errno != 0) ret = -errno; return ret; } static int data_to_uint64_ptr(data_t *data, uint64_t *val) { int ret = 0; errno = 0; *val = strtoull(data->data, NULL, 0); if (errno != 0) ret = -errno; return ret; } static int data_to_double_ptr(data_t *data, double *val) { int ret = 0; if (!data || !val) { ret = -EINVAL; goto err; } errno = 0; *val = strtod(data->data, NULL); if (errno != 0) ret = -errno; err: return ret; } int dict_get_int8(dict_t *this, char *key, int8_t *val) { data_t *data = NULL; int ret = 0; if (!val) { ret = -EINVAL; goto err; } ret = dict_get_with_ref(this, key, &data); if (ret != 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_INT, key, -EINVAL); ret = data_to_int8_ptr(data, val); err: if (data) data_unref(data); return ret; } int dict_set_int8(dict_t *this, char *key, int8_t val) { data_t *data = NULL; int ret = 0; data = data_from_int8(val); if (!data) { ret = -EINVAL; goto err; } ret = dict_set(this, key, data); if (ret < 0) data_destroy(data); err: return ret; } int dict_get_int16(dict_t *this, char *key, int16_t *val) { data_t *data = NULL; int ret = 0; if (!val) { ret = -EINVAL; goto err; } ret = dict_get_with_ref(this, key, &data); if (ret != 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_INT, key, -EINVAL); ret = data_to_int16_ptr(data, val); err: if (data) data_unref(data); return ret; } int dict_set_int16(dict_t *this, char *key, int16_t val) { data_t *data = NULL; int ret = 0; data = data_from_int16(val); if (!data) { ret = -EINVAL; goto err; } ret = dict_set(this, key, data); if (ret < 0) data_destroy(data); err: return ret; } int dict_get_int32n(dict_t *this, char *key, const int keylen, int32_t *val) { data_t *data = NULL; int ret = 0; if (!val) { ret = -EINVAL; goto err; } ret = dict_get_with_refn(this, key, keylen, &data); if (ret != 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_INT, key, -EINVAL); ret = data_to_int32_ptr(data, val); err: if (data) data_unref(data); return ret; } int dict_get_int32(dict_t *this, char *key, int32_t *val) { data_t *data = NULL; int ret = 0; if (!val) { ret = -EINVAL; goto err; } ret = dict_get_with_ref(this, key, &data); if (ret != 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_INT, key, -EINVAL); ret = data_to_int32_ptr(data, val); err: if (data) data_unref(data); return ret; } int dict_set_int32n(dict_t *this, char *key, const int keylen, int32_t val) { data_t *data = NULL; int ret = 0; data = data_from_int32(val); if (!data) { ret = -EINVAL; goto err; } ret = dict_setn(this, key, keylen, data); if (ret < 0) data_destroy(data); err: return ret; } int dict_set_int32(dict_t *this, char *key, int32_t val) { data_t *data = data_from_int32(val); int ret = 0; if (!data) { ret = -EINVAL; goto err; } ret = dict_set(this, key, data); if (ret < 0) data_destroy(data); err: return ret; } int dict_get_int64(dict_t *this, char *key, int64_t *val) { data_t *data = NULL; int ret = 0; if (!val) { ret = -EINVAL; goto err; } ret = dict_get_with_ref(this, key, &data); if (ret != 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_INT, key, -EINVAL); ret = data_to_int64_ptr(data, val); err: if (data) data_unref(data); return ret; } int dict_set_int64(dict_t *this, char *key, int64_t val) { data_t *data = data_from_int64(val); int ret = 0; if (!data) { ret = -EINVAL; goto err; } ret = dict_set(this, key, data); if (ret < 0) data_destroy(data); err: return ret; } int dict_get_uint16(dict_t *this, char *key, uint16_t *val) { data_t *data = NULL; int ret = 0; if (!val) { ret = -EINVAL; goto err; } ret = dict_get_with_ref(this, key, &data); if (ret != 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_UINT, key, -EINVAL); ret = data_to_uint16_ptr(data, val); err: if (data) data_unref(data); return ret; } int dict_set_uint16(dict_t *this, char *key, uint16_t val) { data_t *data = data_from_uint16(val); int ret = 0; if (!data) { ret = -EINVAL; goto err; } ret = dict_set(this, key, data); if (ret < 0) data_destroy(data); err: return ret; } int dict_get_uint32(dict_t *this, char *key, uint32_t *val) { data_t *data = NULL; int ret = 0; if (!val) { ret = -EINVAL; goto err; } ret = dict_get_with_ref(this, key, &data); if (ret != 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_UINT, key, -EINVAL); ret = data_to_uint32_ptr(data, val); err: if (data) data_unref(data); return ret; } int dict_set_uint32(dict_t *this, char *key, uint32_t val) { data_t *data = data_from_uint32(val); int ret = 0; if (!data) { ret = -EINVAL; goto err; } ret = dict_set(this, key, data); if (ret < 0) data_destroy(data); err: return ret; } int dict_get_uint64(dict_t *this, char *key, uint64_t *val) { data_t *data = NULL; int ret = 0; if (!val) { ret = -EINVAL; goto err; } ret = dict_get_with_ref(this, key, &data); if (ret != 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_UINT, key, -EINVAL); ret = data_to_uint64_ptr(data, val); err: if (data) data_unref(data); return ret; } int dict_set_uint64(dict_t *this, char *key, uint64_t val) { data_t *data = data_from_uint64(val); int ret = 0; if (!data) { ret = -EINVAL; goto err; } ret = dict_set(this, key, data); if (ret < 0) data_destroy(data); err: return ret; } /* * dict_check_flag can be used to check a one bit flag in an array of flags * The flag argument indicates the bit position (within the array of bits). * Currently limited to max of 256 flags for a key. * return value, * 1 : flag is set * 0 : flag is not set * <0: Error */ int dict_check_flag(dict_t *this, char *key, int flag) { data_t *data = NULL; int ret = -ENOENT; ret = dict_get_with_ref(this, key, &data); if (ret < 0) { return ret; } if (BIT_VALUE((unsigned char *)(data->data), flag)) ret = 1; else ret = 0; data_unref(data); return ret; } /* * _dict_modify_flag can be used to set/clear a bit flag in an array of flags * flag: indicates the bit position. limited to max of DICT_MAX_FLAGS. * op: Indicates operation DICT_FLAG_SET / DICT_FLAG_CLEAR */ static int _dict_modify_flag(dict_t *this, char *key, int flag, int op) { data_t *data = NULL; int ret = 0; data_pair_t *pair = NULL; char *ptr = NULL; int hashval = 0; uint32_t hash; if (!this || !key) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "dict OR key (%s) is NULL", key); ret = -EINVAL; goto err; } /* * Using a size of 32 bytes to support max of 256 * flags in a single key. This should be suffcient. */ GF_ASSERT(flag >= 0 && flag < DICT_MAX_FLAGS); hash = (uint32_t)XXH64(key, strlen(key), 0); LOCK(&this->lock); { pair = dict_lookup_common(this, key, hash); if (pair) { data = pair->value; if (op == DICT_FLAG_SET) BIT_SET((unsigned char *)(data->data), flag); else BIT_CLEAR((unsigned char *)(data->data), flag); } else { ptr = GF_CALLOC(1, DICT_MAX_FLAGS / 8, gf_common_mt_char); if (!ptr) { gf_msg("dict", GF_LOG_ERROR, ENOMEM, LG_MSG_NO_MEMORY, "unable to allocate flag bit array"); ret = -ENOMEM; goto err; } data = data_from_dynptr(ptr, DICT_MAX_FLAGS / 8); if (!data) { gf_msg("dict", GF_LOG_ERROR, ENOMEM, LG_MSG_NO_MEMORY, "unable to allocate data"); GF_FREE(ptr); ret = -ENOMEM; goto err; } if (op == DICT_FLAG_SET) BIT_SET((unsigned char *)(data->data), flag); else BIT_CLEAR((unsigned char *)(data->data), flag); if (this->free_pair_in_use) { pair = mem_get0(THIS->ctx->dict_pair_pool); if (!pair) { gf_msg("dict", GF_LOG_ERROR, ENOMEM, LG_MSG_NO_MEMORY, "unable to allocate dict pair"); ret = -ENOMEM; goto err; } } else { pair = &this->free_pair; this->free_pair_in_use = _gf_true; } pair->key = (char *)GF_MALLOC(strlen(key) + 1, gf_common_mt_char); if (!pair->key) { gf_msg("dict", GF_LOG_ERROR, ENOMEM, LG_MSG_NO_MEMORY, "unable to allocate dict pair"); ret = -ENOMEM; goto err; } strcpy(pair->key, key); pair->key_hash = hash; pair->value = data_ref(data); hashval = hash % this->hash_size; pair->hash_next = this->members[hashval]; this->members[hashval] = pair; pair->next = this->members_list; pair->prev = NULL; if (this->members_list) this->members_list->prev = pair; this->members_list = pair; this->count++; if (this->max_count < this->count) this->max_count = this->count; } } UNLOCK(&this->lock); return 0; err: if (key && this) UNLOCK(&this->lock); if (pair) { if (pair->key) free(pair->key); if (pair == &this->free_pair) { this->free_pair_in_use = _gf_false; } else { mem_put(pair); } } if (data) data_destroy(data); gf_msg("dict", GF_LOG_ERROR, EINVAL, LG_MSG_DICT_SET_FAILED, "unable to set key (%s) in dict ", key); return ret; } /* * Todo: * Add below primitives as needed: * dict_check_flags(this, key, flag...): variadic function to check * multiple flags at a time. * dict_set_flags(this, key, flag...): set multiple flags * dict_clear_flags(this, key, flag...): reset multiple flags */ int dict_set_flag(dict_t *this, char *key, int flag) { return _dict_modify_flag(this, key, flag, DICT_FLAG_SET); } int dict_clear_flag(dict_t *this, char *key, int flag) { return _dict_modify_flag(this, key, flag, DICT_FLAG_CLEAR); } int dict_get_double(dict_t *this, char *key, double *val) { data_t *data = NULL; int ret = 0; if (!val) { ret = -EINVAL; goto err; } ret = dict_get_with_ref(this, key, &data); if (ret != 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_DOUBLE, key, -EINVAL); ret = data_to_double_ptr(data, val); err: if (data) data_unref(data); return ret; } int dict_set_double(dict_t *this, char *key, double val) { data_t *data = data_from_double(val); int ret = 0; if (!data) { ret = -EINVAL; goto err; } ret = dict_set(this, key, data); if (ret < 0) data_destroy(data); err: return ret; } int dict_set_static_ptr(dict_t *this, char *key, void *ptr) { data_t *data = data_from_ptr_common(ptr, _gf_true); int ret = 0; if (!data) { ret = -EINVAL; goto err; } ret = dict_set(this, key, data); if (ret < 0) data_destroy(data); err: return ret; } int dict_set_dynptr(dict_t *this, char *key, void *ptr, size_t len) { data_t *data = data_from_dynptr(ptr, len); int ret = 0; if (!data) { ret = -EINVAL; goto err; } ret = dict_set(this, key, data); if (ret < 0) data_destroy(data); err: return ret; } int dict_get_ptr(dict_t *this, char *key, void **ptr) { data_t *data = NULL; int ret = 0; if (!ptr) { ret = -EINVAL; goto err; } ret = dict_get_with_ref(this, key, &data); if (ret != 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_PTR, key, -EINVAL); *ptr = data->data; err: if (data) data_unref(data); return ret; } int dict_get_ptr_and_len(dict_t *this, char *key, void **ptr, int *len) { data_t *data = NULL; int ret = 0; if (!ptr) { ret = -EINVAL; goto err; } ret = dict_get_with_ref(this, key, &data); if (ret != 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_PTR, key, -EINVAL); *len = data->len; *ptr = data->data; err: if (data) data_unref(data); return ret; } /* Get string - with known key length */ int dict_get_strn(dict_t *this, char *key, const int keylen, char **str) { data_t *data = NULL; int ret = -EINVAL; if (!str) { goto err; } ret = dict_get_with_refn(this, key, keylen, &data); if (ret < 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_STR, key, -EINVAL); *str = data->data; err: if (data) data_unref(data); return ret; } int dict_get_str(dict_t *this, char *key, char **str) { data_t *data = NULL; int ret = -EINVAL; if (!str) { goto err; } ret = dict_get_with_ref(this, key, &data); if (ret < 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_STR, key, -EINVAL); *str = data->data; err: if (data) data_unref(data); return ret; } int dict_set_str(dict_t *this, char *key, char *str) { data_t *data = str_to_data(str); int ret = 0; if (!data) { ret = -EINVAL; goto err; } ret = dict_set(this, key, data); if (ret < 0) data_destroy(data); err: return ret; } /* Set string - with known key length */ int dict_set_strn(dict_t *this, char *key, const int keylen, char *str) { data_t *data = NULL; int ret = 0; data = str_to_data(str); if (!data) { ret = -EINVAL; goto err; } ret = dict_setn(this, key, keylen, data); if (ret < 0) data_destroy(data); err: return ret; } /* Set string - with known key length and known value length */ int dict_set_nstrn(dict_t *this, char *key, const int keylen, char *str, const int vallen) { data_t *data = strn_to_data(str, vallen); int ret = 0; if (!data) { ret = -EINVAL; goto err; } ret = dict_setn(this, key, keylen, data); if (ret < 0) data_destroy(data); err: return ret; } int dict_set_dynstr_with_alloc(dict_t *this, char *key, const char *str) { char *alloc_str = gf_strdup(str); int ret = -1; if (!alloc_str) return ret; ret = dict_set_dynstr(this, key, alloc_str); if (ret == -EINVAL) GF_FREE(alloc_str); return ret; } int dict_set_dynstr(dict_t *this, char *key, char *str) { const int keylen = strlen(key); return dict_set_dynstrn(this, key, keylen, str); } int dict_set_dynstrn(dict_t *this, char *key, const int keylen, char *str) { data_t *data = data_from_dynstr(str); int ret = 0; if (!data) { ret = -EINVAL; goto err; } ret = dict_setn(this, key, keylen, data); if (ret < 0) data_destroy(data); err: return ret; } /* This function is called only by the volgen for now. Check how else you can handle it */ int dict_set_option(dict_t *this, char *key, char *str) { data_t *data = data_from_dynstr(str); int ret = 0; if (!data) { ret = -EINVAL; goto err; } data->data_type = GF_DATA_TYPE_STR_OLD; ret = dict_set(this, key, data); if (ret < 0) data_destroy(data); err: return ret; } int dict_add_dynstr_with_alloc(dict_t *this, char *key, char *str) { data_t *data = NULL; int ret = 0; char *alloc_str = gf_strdup(str); if (!alloc_str) goto out; data = data_from_dynstr(alloc_str); if (!data) { GF_FREE(alloc_str); ret = -EINVAL; goto out; } ret = dict_add(this, key, data); if (ret < 0) data_destroy(data); out: return ret; } int dict_get_bin(dict_t *this, char *key, void **bin) { data_t *data = NULL; int ret = -EINVAL; if (!bin) { goto err; } ret = dict_get_with_ref(this, key, &data); if (ret < 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_PTR, key, ret); *bin = data->data; err: if (data) data_unref(data); return ret; } /******************************************************************** * * dict_set_bin_common: * This is the common function to set key and its value in * dictionary. Flag(is_static) should be set appropriately based * on the type of memory type used for value(*ptr). If flag is set * to false value(*ptr) will be freed using GF_FREE() on destroy. * *******************************************************************/ static int dict_set_bin_common(dict_t *this, char *key, void *ptr, size_t size, gf_boolean_t is_static, gf_dict_data_type_t type) { data_t *data = NULL; int ret = 0; if (size > DICT_KEY_VALUE_MAX_SIZE) { ret = -EINVAL; goto err; } data = bin_to_data(ptr, size); if (!data) { ret = -EINVAL; goto err; } data->is_static = is_static; data->data_type = type; ret = dict_set(this, key, data); if (ret < 0) { /* don't free data->data, let callers handle it */ data->data = NULL; data_destroy(data); } err: return ret; } /******************************************************************** * * dict_set_bin: * Set key and its value in the dictionary. This function should * be called if the value is stored in dynamic memory. * *******************************************************************/ int dict_set_bin(dict_t *this, char *key, void *ptr, size_t size) { return dict_set_bin_common(this, key, ptr, size, _gf_false, GF_DATA_TYPE_PTR); } /******************************************************************** * * dict_set_static_bin: * Set key and its value in the dictionary. This function should * be called if the value is stored in static memory. * *******************************************************************/ int dict_set_static_bin(dict_t *this, char *key, void *ptr, size_t size) { return dict_set_bin_common(this, key, ptr, size, _gf_true, GF_DATA_TYPE_PTR); } /* */ int dict_set_gfuuid(dict_t *this, char *key, uuid_t gfid, bool is_static) { return dict_set_bin_common(this, key, gfid, sizeof(uuid_t), is_static, GF_DATA_TYPE_GFUUID); } int dict_get_gfuuid(dict_t *this, char *key, uuid_t *gfid) { data_t *data = NULL; int ret = -EINVAL; if (!gfid) { goto err; } ret = dict_get_with_ref(this, key, &data); if (ret < 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_GFUUID, key, -EINVAL); memcpy(*gfid, data->data, min(data->len, sizeof(uuid_t))); err: if (data) data_unref(data); return ret; } int dict_set_mdata(dict_t *this, char *key, struct mdata_iatt *mdata, bool is_static) { return dict_set_bin_common(this, key, mdata, sizeof(struct mdata_iatt), is_static, GF_DATA_TYPE_MDATA); } int dict_get_mdata(dict_t *this, char *key, struct mdata_iatt *mdata) { data_t *data = NULL; int ret = -EINVAL; if (!mdata) { goto err; } ret = dict_get_with_ref(this, key, &data); if (ret < 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_MDATA, key, -EINVAL); if (data->len < sizeof(struct mdata_iatt)) { gf_msg("glusterfs", GF_LOG_ERROR, ENOBUFS, LG_MSG_UNDERSIZED_BUF, "data value for '%s' is smaller than expected", key); ret = -ENOBUFS; goto err; } memcpy(mdata, data->data, min(data->len, sizeof(struct mdata_iatt))); err: if (data) data_unref(data); return ret; } int dict_set_iatt(dict_t *this, char *key, struct iatt *iatt, bool is_static) { return dict_set_bin_common(this, key, iatt, sizeof(struct iatt), is_static, GF_DATA_TYPE_IATT); } int dict_get_iatt(dict_t *this, char *key, struct iatt *iatt) { data_t *data = NULL; int ret = -EINVAL; if (!iatt) { goto err; } ret = dict_get_with_ref(this, key, &data); if (ret < 0) { goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_IATT, key, -EINVAL); memcpy(iatt, data->data, min(data->len, sizeof(struct iatt))); err: if (data) data_unref(data); return ret; } /** * dict_get_str_boolean - get a boolean value based on string representation. * * @this : dictionary * @key : dictionary key queried * @default_val : default value if key not found * * @return : @default_val if key not found * : boolean interpretation of @this[@key] if it makes sense * (ie., "on", "true", "enable" ...) * : -1 if error occurs or @this[@key] doesn't make sens as * boolean * * So if you query a boolean option, then via @default_val you can choose * between following patterns: * * - fall back to _gf_false if @key is not set [@default_val = 0] * - fall back to _gf_true if @key is not set [@default_val = 1] * - regard as failure if @key is not set [@default_val = -1] * - handle specially (not as error) if @key is not set * [@default_val = anything else] */ int dict_get_str_boolean(dict_t *this, char *key, int default_val) { data_t *data = NULL; gf_boolean_t boo = _gf_false; int ret = 0; ret = dict_get_with_ref(this, key, &data); if (ret < 0) { if (ret == -ENOENT) ret = default_val; else ret = -1; goto err; } VALIDATE_DATA_AND_LOG(data, GF_DATA_TYPE_INT, key, -EINVAL); ret = gf_string2boolean(data->data, &boo); if (ret == -1) goto err; ret = boo; err: if (data) data_unref(data); return ret; } int dict_rename_key(dict_t *this, char *key, char *replace_key) { data_pair_t *pair = NULL; int ret = -EINVAL; uint32_t hash; uint32_t replacekey_hash; int replacekey_len; /* replacing a key by itself is a NO-OP */ if (strcmp(key, replace_key) == 0) return 0; if (!this) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "dict is NULL"); return ret; } hash = (uint32_t)XXH64(key, strlen(key), 0); replacekey_len = strlen(replace_key); replacekey_hash = (uint32_t)XXH64(replace_key, replacekey_len, 0); LOCK(&this->lock); { /* no need to data_ref(pair->value), dict_set_lk() does it */ pair = dict_lookup_common(this, key, hash); if (!pair) ret = -ENODATA; else ret = dict_set_lk(this, replace_key, replacekey_len, pair->value, replacekey_hash, 1); } UNLOCK(&this->lock); if (!ret) /* only delete the key on success */ dict_del(this, key); return ret; } /** * Serialization format: * -------- -------- -------- ----------- ------------- * | count | key len | val len | key \0| value * ---------------------------------------- ------------- * 4 4 4 */ /** * dict_serialized_length_lk - return the length of serialized dict. This * procedure has to be called with this->lock held. * * @this : dict to be serialized * @return: success: len * : failure: -errno */ int dict_serialized_length_lk(dict_t *this) { int ret = -EINVAL; int count = this->count; int len = DICT_HDR_LEN; data_pair_t *pair = this->members_list; if (count < 0) { gf_msg("dict", GF_LOG_ERROR, EINVAL, LG_MSG_COUNT_LESS_THAN_ZERO, "count (%d) < 0!", count); goto out; } while (count) { if (!pair) { gf_msg("dict", GF_LOG_ERROR, EINVAL, LG_MSG_COUNT_LESS_THAN_DATA_PAIRS, "less than count data pairs found!"); goto out; } len += DICT_DATA_HDR_KEY_LEN + DICT_DATA_HDR_VAL_LEN; if (!pair->key) { gf_msg("dict", GF_LOG_ERROR, EINVAL, LG_MSG_NULL_PTR, "pair->key is null!"); goto out; } len += strlen(pair->key) + 1 /* for '\0' */; if (!pair->value) { gf_msg("dict", GF_LOG_ERROR, EINVAL, LG_MSG_NULL_PTR, "pair->value is null!"); goto out; } if (pair->value->len < 0) { gf_msg("dict", GF_LOG_ERROR, EINVAL, LG_MSG_VALUE_LENGTH_LESS_THAN_ZERO, "value->len (%d) < 0", pair->value->len); goto out; } len += pair->value->len; pair = pair->next; count--; } ret = len; out: return ret; } /** * dict_serialize_lk - serialize a dictionary into a buffer. This procedure has * to be called with this->lock held. * * @this: dict to serialize * @buf: buffer to serialize into. This must be * at least dict_serialized_length (this) large * * @return: success: 0 * failure: -errno */ static int dict_serialize_lk(dict_t *this, char *buf) { int ret = -1; data_pair_t *pair = this->members_list; int32_t count = this->count; int32_t keylen = 0; int32_t netword = 0; if (count < 0) { gf_msg("dict", GF_LOG_ERROR, 0, LG_MSG_COUNT_LESS_THAN_ZERO, "count (%d) < 0!", count); goto out; } netword = hton32(count); memcpy(buf, &netword, sizeof(netword)); buf += DICT_HDR_LEN; while (count) { if (!pair) { gf_msg("dict", GF_LOG_ERROR, 0, LG_MSG_PAIRS_LESS_THAN_COUNT, "less than count data pairs found!"); goto out; } if (!pair->key) { gf_msg("dict", GF_LOG_ERROR, 0, LG_MSG_NULL_PTR, "pair->key is null!"); goto out; } keylen = strlen(pair->key); netword = hton32(keylen); memcpy(buf, &netword, sizeof(netword)); buf += DICT_DATA_HDR_KEY_LEN; if (!pair->value) { gf_msg("dict", GF_LOG_ERROR, 0, LG_MSG_NULL_PTR, "pair->value is null!"); goto out; } netword = hton32(pair->value->len); memcpy(buf, &netword, sizeof(netword)); buf += DICT_DATA_HDR_VAL_LEN; memcpy(buf, pair->key, keylen); buf += keylen; *buf++ = '\0'; if (pair->value->data) { memcpy(buf, pair->value->data, pair->value->len); buf += pair->value->len; } pair = pair->next; count--; } ret = 0; out: return ret; } /** * dict_serialized_length - return the length of serialized dict * * @this: dict to be serialized * @return: success: len * : failure: -errno */ int dict_serialized_length(dict_t *this) { int ret = -EINVAL; if (!this) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "dict is null!"); goto out; } LOCK(&this->lock); { ret = dict_serialized_length_lk(this); } UNLOCK(&this->lock); out: return ret; } /** * dict_serialize - serialize a dictionary into a buffer * * @this: dict to serialize * @buf: buffer to serialize into. This must be * at least dict_serialized_length (this) large * * @return: success: 0 * failure: -errno */ int dict_serialize(dict_t *this, char *buf) { int ret = -1; if (!this || !buf) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "dict is null!"); goto out; } LOCK(&this->lock); { ret = dict_serialize_lk(this, buf); } UNLOCK(&this->lock); out: return ret; } /** * dict_unserialize - unserialize a buffer into a dict * * @buf: buf containing serialized dict * @size: size of the @buf * @fill: dict to fill in * * @return: success: 0 * failure: -errno */ int32_t dict_unserialize(char *orig_buf, int32_t size, dict_t **fill) { char *buf = orig_buf; int ret = -1; int32_t count = 0; int i = 0; data_t *value = NULL; char *key = NULL; int32_t keylen = 0; int32_t vallen = 0; int32_t hostord = 0; if (!buf) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "buf is null!"); goto out; } if (size == 0) { gf_msg_callingfn("dict", GF_LOG_ERROR, EINVAL, LG_MSG_INVALID_ARG, "size is 0!"); goto out; } if (!fill) { gf_msg_callingfn("dict", GF_LOG_ERROR, EINVAL, LG_MSG_INVALID_ARG, "fill is null!"); goto out; } if (!*fill) { gf_msg_callingfn("dict", GF_LOG_ERROR, EINVAL, LG_MSG_INVALID_ARG, "*fill is null!"); goto out; } if ((buf + DICT_HDR_LEN) > (orig_buf + size)) { gf_msg_callingfn("dict", GF_LOG_ERROR, 0, LG_MSG_UNDERSIZED_BUF, "undersized buffer " "passed. available (%lu) < required (%lu)", (long)(orig_buf + size), (long)(buf + DICT_HDR_LEN)); goto out; } memcpy(&hostord, buf, sizeof(hostord)); count = ntoh32(hostord); buf += DICT_HDR_LEN; if (count < 0) { gf_msg("dict", GF_LOG_ERROR, 0, LG_MSG_COUNT_LESS_THAN_ZERO, "count (%d) <= 0", count); goto out; } /* count will be set by the dict_set's below */ (*fill)->count = 0; for (i = 0; i < count; i++) { if ((buf + DICT_DATA_HDR_KEY_LEN) > (orig_buf + size)) { gf_msg_callingfn("dict", GF_LOG_ERROR, 0, LG_MSG_UNDERSIZED_BUF, "undersized " "buffer passed. available (%lu) < " "required (%lu)", (long)(orig_buf + size), (long)(buf + DICT_DATA_HDR_KEY_LEN)); goto out; } memcpy(&hostord, buf, sizeof(hostord)); keylen = ntoh32(hostord); buf += DICT_DATA_HDR_KEY_LEN; if ((buf + DICT_DATA_HDR_VAL_LEN) > (orig_buf + size)) { gf_msg_callingfn("dict", GF_LOG_ERROR, 0, LG_MSG_UNDERSIZED_BUF, "undersized " "buffer passed. available (%lu) < " "required (%lu)", (long)(orig_buf + size), (long)(buf + DICT_DATA_HDR_VAL_LEN)); goto out; } memcpy(&hostord, buf, sizeof(hostord)); vallen = ntoh32(hostord); buf += DICT_DATA_HDR_VAL_LEN; if ((keylen < 0) || (vallen < 0)) { gf_msg_callingfn("dict", GF_LOG_ERROR, 0, LG_MSG_UNDERSIZED_BUF, "undersized length passed " "key:%d val:%d", keylen, vallen); goto out; } if ((buf + keylen) > (orig_buf + size)) { gf_msg_callingfn("dict", GF_LOG_ERROR, 0, LG_MSG_UNDERSIZED_BUF, "undersized buffer passed. " "available (%lu) < required (%lu)", (long)(orig_buf + size), (long)(buf + keylen)); goto out; } key = buf; buf += keylen + 1; /* for '\0' */ if ((buf + vallen) > (orig_buf + size)) { gf_msg_callingfn("dict", GF_LOG_ERROR, 0, LG_MSG_UNDERSIZED_BUF, "undersized buffer passed. " "available (%lu) < required (%lu)", (long)(orig_buf + size), (long)(buf + vallen)); goto out; } value = get_new_data(); if (!value) { ret = -1; goto out; } value->len = vallen; value->data = gf_memdup(buf, vallen); value->data_type = GF_DATA_TYPE_STR_OLD; value->is_static = _gf_false; buf += vallen; ret = dict_addn(*fill, key, keylen, value); if (ret < 0) goto out; } ret = 0; out: return ret; } /** * dict_allocate_and_serialize - serialize a dictionary into an allocated buffer * * @this: dict to serialize * @buf: pointer to pointer to character. The allocated buffer is stored in * this pointer. The buffer has to be freed by the caller. * * @return: success: 0 * failure: -errno */ int32_t dict_allocate_and_serialize(dict_t *this, char **buf, u_int *length) { int ret = -EINVAL; ssize_t len = 0; if (!this || !buf) { gf_msg_debug("dict", 0, "dict OR buf is NULL"); goto out; } LOCK(&this->lock); { len = dict_serialized_length_lk(this); if (len < 0) { ret = len; goto unlock; } *buf = GF_MALLOC(len, gf_common_mt_char); if (*buf == NULL) { ret = -ENOMEM; goto unlock; } ret = dict_serialize_lk(this, *buf); if (ret < 0) { GF_FREE(*buf); *buf = NULL; goto unlock; } if (length != NULL) { *length = len; } } unlock: UNLOCK(&this->lock); out: return ret; } /** * dict_serialize_value_with_delim_lk: serialize the values in the dictionary * into a buffer separated by delimiter (except the last) * * @this : dictionary to serialize * @buf : the buffer to store the serialized data * @serz_len : the length of the serialized data (excluding the last delimiter) * @delimiter : the delimiter to separate the values * * @return : 0 -> success * : -errno -> failure */ int dict_serialize_value_with_delim_lk(dict_t *this, char *buf, int32_t *serz_len, char delimiter) { int ret = -1; int32_t count = this->count; int32_t vallen = 0; int32_t total_len = 0; data_pair_t *pair = this->members_list; if (!buf) { gf_msg("dict", GF_LOG_ERROR, EINVAL, LG_MSG_INVALID_ARG, "buf is null"); goto out; } if (count < 0) { gf_msg("dict", GF_LOG_ERROR, EINVAL, LG_MSG_INVALID_ARG, "count (%d) < 0", count); goto out; } while (count) { if (!pair) { gf_msg("dict", GF_LOG_ERROR, 0, LG_MSG_PAIRS_LESS_THAN_COUNT, "less than count data pairs found"); goto out; } if (!pair->key || !pair->value) { gf_msg("dict", GF_LOG_ERROR, 0, LG_MSG_KEY_OR_VALUE_NULL, "key or value is null"); goto out; } if (!pair->value->data) { gf_msg("dict", GF_LOG_ERROR, 0, LG_MSG_NULL_VALUE_IN_DICT, "null value found in dict"); goto out; } vallen = pair->value->len - 1; // length includes \0 memcpy(buf, pair->value->data, vallen); buf += vallen; *buf++ = delimiter; total_len += (vallen + 1); pair = pair->next; count--; } *--buf = '\0'; // remove the last delimiter total_len--; // adjust the length ret = 0; if (serz_len) *serz_len = total_len; out: return ret; } int dict_serialize_value_with_delim(dict_t *this, char *buf, int32_t *serz_len, char delimiter) { int ret = -1; if (!this || !buf) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "dict is null!"); goto out; } LOCK(&this->lock); { ret = dict_serialize_value_with_delim_lk(this, buf, serz_len, delimiter); } UNLOCK(&this->lock); out: return ret; } int dict_dump_to_str(dict_t *dict, char *dump, int dumpsize, char *format) { int ret = 0; int dumplen = 0; data_pair_t *trav = NULL; if (!dict) return 0; for (trav = dict->members_list; trav; trav = trav->next) { ret = snprintf(&dump[dumplen], dumpsize - dumplen, format, trav->key, trav->value->data); if ((ret == -1) || !ret) return ret; dumplen += ret; } return 0; } void dict_dump_to_log(dict_t *dict) { int ret = -1; char *dump = NULL; const int dump_size = 64 * 1024; char *format = "(%s:%s)"; if (!dict) { gf_msg_callingfn("dict", GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "dict is NULL"); goto out; } dump = GF_MALLOC(dump_size, gf_common_mt_char); if (!dump) { gf_msg_callingfn("dict", GF_LOG_WARNING, ENOMEM, LG_MSG_NO_MEMORY, "dump buffer is NULL"); goto out; } ret = dict_dump_to_str(dict, dump, dump_size, format); if (ret) { gf_msg("dict", GF_LOG_WARNING, 0, LG_MSG_FAILED_TO_LOG_DICT, "Failed to log dictionary"); goto out; } gf_msg("dict", GF_LOG_INFO, 0, LG_MSG_DICT_ERROR, "dict=%p (%s)", dict, dump); out: GF_FREE(dump); return; } void dict_dump_to_statedump(dict_t *dict, char *dict_name, char *domain) { int ret = -1; char *dump = NULL; const int dump_size = 64 * 1024; char key[4096] = { 0, }; char *format = "\n\t%s:%s"; if (!dict) { gf_msg_callingfn(domain, GF_LOG_WARNING, EINVAL, LG_MSG_INVALID_ARG, "dict is NULL"); goto out; } dump = GF_MALLOC(dump_size, gf_common_mt_char); if (!dump) { gf_msg_callingfn(domain, GF_LOG_WARNING, ENOMEM, LG_MSG_NO_MEMORY, "dump buffer is NULL"); goto out; } ret = dict_dump_to_str(dict, dump, dump_size, format); if (ret) { gf_msg(domain, GF_LOG_WARNING, 0, LG_MSG_FAILED_TO_LOG_DICT, "Failed to log dictionary %s", dict_name); goto out; } gf_proc_dump_build_key(key, domain, "%s", dict_name); gf_proc_dump_write(key, "%s", dump); out: GF_FREE(dump); return; } dict_t * dict_for_key_value(const char *name, const char *value, size_t size, gf_boolean_t is_static) { dict_t *xattr = dict_new(); int ret = 0; if (!xattr) return NULL; if (is_static) ret = dict_set_static_bin(xattr, (char *)name, (void *)value, size); else ret = dict_set_bin(xattr, (char *)name, (void *)value, size); if (ret) { dict_destroy(xattr); xattr = NULL; } return xattr; } /* * "strings" should be NULL terminated strings array. */ int dict_has_key_from_array(dict_t *dict, char **strings, gf_boolean_t *result) { int i = 0; uint32_t hash = 0; if (!dict || !strings || !result) return -EINVAL; LOCK(&dict->lock); { for (i = 0; strings[i]; i++) { hash = (uint32_t)XXH64(strings[i], strlen(strings[i]), 0); if (dict_lookup_common(dict, strings[i], hash)) { *result = _gf_true; goto unlock; } } *result = _gf_false; } unlock: UNLOCK(&dict->lock); return 0; }