/* SPDX-License-Identifier: GPL-2.0-only */ /* Copyright (C) 2013 Jozsef Kadlecsik */ #ifndef _IP_SET_HASH_GEN_H #define _IP_SET_HASH_GEN_H #include #include #include #include #include #define __ipset_dereference(p) \ rcu_dereference_protected(p, 1) #define ipset_dereference_nfnl(p) \ rcu_dereference_protected(p, \ lockdep_nfnl_is_held(NFNL_SUBSYS_IPSET)) #define ipset_dereference_set(p, set) \ rcu_dereference_protected(p, \ lockdep_nfnl_is_held(NFNL_SUBSYS_IPSET) || \ lockdep_is_held(&(set)->lock)) #define ipset_dereference_bh_nfnl(p) \ rcu_dereference_bh_check(p, \ lockdep_nfnl_is_held(NFNL_SUBSYS_IPSET)) /* Hashing which uses arrays to resolve clashing. The hash table is resized * (doubled) when searching becomes too long. * Internally jhash is used with the assumption that the size of the * stored data is a multiple of sizeof(u32). * * Readers and resizing * * Resizing can be triggered by userspace command only, and those * are serialized by the nfnl mutex. During resizing the set is * read-locked, so the only possible concurrent operations are * the kernel side readers. Those must be protected by proper RCU locking. */ /* Number of elements to store in an initial array block */ #define AHASH_INIT_SIZE 2 /* Max number of elements to store in an array block */ #define AHASH_MAX_SIZE (6 * AHASH_INIT_SIZE) /* Max muber of elements in the array block when tuned */ #define AHASH_MAX_TUNED 64 #define AHASH_MAX(h) ((h)->bucketsize) /* Max number of elements can be tuned */ #ifdef IP_SET_HASH_WITH_MULTI static u8 tune_bucketsize(u8 curr, u32 multi) { u32 n; if (multi < curr) return curr; n = curr + AHASH_INIT_SIZE; /* Currently, at listing one hash bucket must fit into a message. * Therefore we have a hard limit here. */ return n > curr && n <= AHASH_MAX_TUNED ? n : curr; } #define TUNE_BUCKETSIZE(h, multi) \ ((h)->bucketsize = tune_bucketsize((h)->bucketsize, multi)) #else #define TUNE_BUCKETSIZE(h, multi) #endif /* A hash bucket */ struct hbucket { struct rcu_head rcu; /* for call_rcu_bh */ /* Which positions are used in the array */ DECLARE_BITMAP(used, AHASH_MAX_TUNED); u8 size; /* size of the array */ u8 pos; /* position of the first free entry */ unsigned char value[] /* the array of the values */ __aligned(__alignof__(u64)); }; /* Region size for locking == 2^HTABLE_REGION_BITS */ #define HTABLE_REGION_BITS 10 #define ahash_numof_locks(htable_bits) \ ((htable_bits) < HTABLE_REGION_BITS ? 1 \ : jhash_size((htable_bits) - HTABLE_REGION_BITS)) #define ahash_sizeof_regions(htable_bits) \ (ahash_numof_locks(htable_bits) * sizeof(struct ip_set_region)) #define ahash_region(n, htable_bits) \ ((n) % ahash_numof_locks(htable_bits)) #define ahash_bucket_start(h, htable_bits) \ ((htable_bits) < HTABLE_REGION_BITS ? 0 \ : (h) * jhash_size(HTABLE_REGION_BITS)) #define ahash_bucket_end(h, htable_bits) \ ((htable_bits) < HTABLE_REGION_BITS ? jhash_size(htable_bits) \ : ((h) + 1) * jhash_size(HTABLE_REGION_BITS)) struct htable_gc { struct delayed_work dwork; struct ip_set *set; /* Set the gc belongs to */ u32 region; /* Last gc run position */ }; /* The hash table: the table size stored here in order to make resizing easy */ struct htable { atomic_t ref; /* References for resizing */ atomic_t uref; /* References for dumping and gc */ u8 htable_bits; /* size of hash table == 2^htable_bits */ u32 maxelem; /* Maxelem per region */ struct ip_set_region *hregion; /* Region locks and ext sizes */ struct hbucket __rcu *bucket[]; /* hashtable buckets */ }; #define hbucket(h, i) ((h)->bucket[i]) #define ext_size(n, dsize) \ (sizeof(struct hbucket) + (n) * (dsize)) #ifndef IPSET_NET_COUNT #define IPSET_NET_COUNT 1 #endif /* Book-keeping of the prefixes added to the set */ struct net_prefixes { u32 nets[IPSET_NET_COUNT]; /* number of elements for this cidr */ u8 cidr[IPSET_NET_COUNT]; /* the cidr value */ }; /* Compute the hash table size */ static size_t htable_size(u8 hbits) { size_t hsize; /* We must fit both into u32 in jhash and size_t */ if (hbits > 31) return 0; hsize = jhash_size(hbits); if ((((size_t)-1) - sizeof(struct htable)) / sizeof(struct hbucket *) < hsize) return 0; return hsize * sizeof(struct hbucket *) + sizeof(struct htable); } /* Compute htable_bits from the user input parameter hashsize */ static u8 htable_bits(u32 hashsize) { /* Assume that hashsize == 2^htable_bits */ u8 bits = fls(hashsize - 1); if (jhash_size(bits) != hashsize) /* Round up to the first 2^n value */ bits = fls(hashsize); return bits; } #ifdef IP_SET_HASH_WITH_NETS #if IPSET_NET_COUNT > 1 #define __CIDR(cidr, i) (cidr[i]) #else #define __CIDR(cidr, i) (cidr) #endif /* cidr + 1 is stored in net_prefixes to support /0 */ #define NCIDR_PUT(cidr) ((cidr) + 1) #define NCIDR_GET(cidr) ((cidr) - 1) #ifdef IP_SET_HASH_WITH_NETS_PACKED /* When cidr is packed with nomatch, cidr - 1 is stored in the data entry */ #define DCIDR_PUT(cidr) ((cidr) - 1) #define DCIDR_GET(cidr, i) (__CIDR(cidr, i) + 1) #else #define DCIDR_PUT(cidr) (cidr) #define DCIDR_GET(cidr, i) __CIDR(cidr, i) #endif #define INIT_CIDR(cidr, host_mask) \ DCIDR_PUT(((cidr) ? NCIDR_GET(cidr) : host_mask)) #ifdef IP_SET_HASH_WITH_NET0 /* cidr from 0 to HOST_MASK value and c = cidr + 1 */ #define NLEN (HOST_MASK + 1) #define CIDR_POS(c) ((c) - 1) #else /* cidr from 1 to HOST_MASK value and c = cidr + 1 */ #define NLEN HOST_MASK #define CIDR_POS(c) ((c) - 2) #endif #else #define NLEN 0 #endif /* IP_SET_HASH_WITH_NETS */ #define SET_ELEM_EXPIRED(set, d) \ (SET_WITH_TIMEOUT(set) && \ ip_set_timeout_expired(ext_timeout(d, set))) #endif /* _IP_SET_HASH_GEN_H */ #ifndef MTYPE #error "MTYPE is not defined!" #endif #ifndef HTYPE #error "HTYPE is not defined!" #endif #ifndef HOST_MASK #error "HOST_MASK is not defined!" #endif /* Family dependent templates */ #undef ahash_data #undef mtype_data_equal #undef mtype_do_data_match #undef mtype_data_set_flags #undef mtype_data_reset_elem #undef mtype_data_reset_flags #undef mtype_data_netmask #undef mtype_data_list #undef mtype_data_next #undef mtype_elem #undef mtype_ahash_destroy #undef mtype_ext_cleanup #undef mtype_add_cidr #undef mtype_del_cidr #undef mtype_ahash_memsize #undef mtype_flush #undef mtype_destroy #undef mtype_same_set #undef mtype_kadt #undef mtype_uadt #undef mtype_add #undef mtype_del #undef mtype_test_cidrs #undef mtype_test #undef mtype_uref #undef mtype_resize #undef mtype_ext_size #undef mtype_resize_ad #undef mtype_head #undef mtype_list #undef mtype_gc_do #undef mtype_gc #undef mtype_gc_init #undef mtype_variant #undef mtype_data_match #undef htype #undef HKEY #define mtype_data_equal IPSET_TOKEN(MTYPE, _data_equal) #ifdef IP_SET_HASH_WITH_NETS #define mtype_do_data_match IPSET_TOKEN(MTYPE, _do_data_match) #else #define mtype_do_data_match(d) 1 #endif #define mtype_data_set_flags IPSET_TOKEN(MTYPE, _data_set_flags) #define mtype_data_reset_elem IPSET_TOKEN(MTYPE, _data_reset_elem) #define mtype_data_reset_flags IPSET_TOKEN(MTYPE, _data_reset_flags) #define mtype_data_netmask IPSET_TOKEN(MTYPE, _data_netmask) #define mtype_data_list IPSET_TOKEN(MTYPE, _data_list) #define mtype_data_next IPSET_TOKEN(MTYPE, _data_next) #define mtype_elem IPSET_TOKEN(MTYPE, _elem) #define mtype_ahash_destroy IPSET_TOKEN(MTYPE, _ahash_destroy) #define mtype_ext_cleanup IPSET_TOKEN(MTYPE, _ext_cleanup) #define mtype_add_cidr IPSET_TOKEN(MTYPE, _add_cidr) #define mtype_del_cidr IPSET_TOKEN(MTYPE, _del_cidr) #define mtype_ahash_memsize IPSET_TOKEN(MTYPE, _ahash_memsize) #define mtype_flush IPSET_TOKEN(MTYPE, _flush) #define mtype_destroy IPSET_TOKEN(MTYPE, _destroy) #define mtype_same_set IPSET_TOKEN(MTYPE, _same_set) #define mtype_kadt IPSET_TOKEN(MTYPE, _kadt) #define mtype_uadt IPSET_TOKEN(MTYPE, _uadt) #define mtype_add IPSET_TOKEN(MTYPE, _add) #define mtype_del IPSET_TOKEN(MTYPE, _del) #define mtype_test_cidrs IPSET_TOKEN(MTYPE, _test_cidrs) #define mtype_test IPSET_TOKEN(MTYPE, _test) #define mtype_uref IPSET_TOKEN(MTYPE, _uref) #define mtype_resize IPSET_TOKEN(MTYPE, _resize) #define mtype_ext_size IPSET_TOKEN(MTYPE, _ext_size) #define mtype_resize_ad IPSET_TOKEN(MTYPE, _resize_ad) #define mtype_head IPSET_TOKEN(MTYPE, _head) #define mtype_list IPSET_TOKEN(MTYPE, _list) #define mtype_gc_do IPSET_TOKEN(MTYPE, _gc_do) #define mtype_gc IPSET_TOKEN(MTYPE, _gc) #define mtype_gc_init IPSET_TOKEN(MTYPE, _gc_init) #define mtype_variant IPSET_TOKEN(MTYPE, _variant) #define mtype_data_match IPSET_TOKEN(MTYPE, _data_match) #ifndef HKEY_DATALEN #define HKEY_DATALEN sizeof(struct mtype_elem) #endif #define htype MTYPE #define HKEY(data, initval, htable_bits) \ ({ \ const u32 *__k = (const u32 *)data; \ u32 __l = HKEY_DATALEN / sizeof(u32); \ \ BUILD_BUG_ON(HKEY_DATALEN % sizeof(u32) != 0); \ \ jhash2(__k, __l, initval) & jhash_mask(htable_bits); \ }) /* The generic hash structure */ struct htype { struct htable __rcu *table; /* the hash table */ struct htable_gc gc; /* gc workqueue */ u32 maxelem; /* max elements in the hash */ u32 initval; /* random jhash init value */ #ifdef IP_SET_HASH_WITH_MARKMASK u32 markmask; /* markmask value for mark mask to store */ #endif u8 bucketsize; /* max elements in an array block */ #ifdef IP_SET_HASH_WITH_NETMASK u8 netmask; /* netmask value for subnets to store */ #endif struct list_head ad; /* Resize add|del backlist */ struct mtype_elem next; /* temporary storage for uadd */ #ifdef IP_SET_HASH_WITH_NETS struct net_prefixes nets[NLEN]; /* book-keeping of prefixes */ #endif }; /* ADD|DEL entries saved during resize */ struct mtype_resize_ad { struct list_head list; enum ipset_adt ad; /* ADD|DEL element */ struct mtype_elem d; /* Element value */ struct ip_set_ext ext; /* Extensions for ADD */ struct ip_set_ext mext; /* Target extensions for ADD */ u32 flags; /* Flags for ADD */ }; #ifdef IP_SET_HASH_WITH_NETS /* Network cidr size book keeping when the hash stores different * sized networks. cidr == real cidr + 1 to support /0. */ static void mtype_add_cidr(struct ip_set *set, struct htype *h, u8 cidr, u8 n) { int i, j; spin_lock_bh(&set->lock); /* Add in increasing prefix order, so larger cidr first */ for (i = 0, j = -1; i < NLEN && h->nets[i].cidr[n]; i++) { if (j != -1) { continue; } else if (h->nets[i].cidr[n] < cidr) { j = i; } else if (h->nets[i].cidr[n] == cidr) { h->nets[CIDR_POS(cidr)].nets[n]++; goto unlock; } } if (j != -1) { for (; i > j; i--) h->nets[i].cidr[n] = h->nets[i - 1].cidr[n]; } h->nets[i].cidr[n] = cidr; h->nets[CIDR_POS(cidr)].nets[n] = 1; unlock: spin_unlock_bh(&set->lock); } static void mtype_del_cidr(struct ip_set *set, struct htype *h, u8 cidr, u8 n) { u8 i, j, net_end = NLEN - 1; spin_lock_bh(&set->lock); for (i = 0; i < NLEN; i++) { if (h->nets[i].cidr[n] != cidr) continue; h->nets[CIDR_POS(cidr)].nets[n]--; if (h->nets[CIDR_POS(cidr)].nets[n] > 0) goto unlock; for (j = i; j < net_end && h->nets[j].cidr[n]; j++) h->nets[j].cidr[n] = h->nets[j + 1].cidr[n]; h->nets[j].cidr[n] = 0; goto unlock; } unlock: spin_unlock_bh(&set->lock); } #endif /* Calculate the actual memory size of the set data */ static size_t mtype_ahash_memsize(const struct htype *h, const struct htable *t) { return sizeof(*h) + sizeof(*t) + ahash_sizeof_regions(t->htable_bits); } /* Get the ith element from the array block n */ #define ahash_data(n, i, dsize) \ ((struct mtype_elem *)((n)->value + ((i) * (dsize)))) static void mtype_ext_cleanup(struct ip_set *set, struct hbucket *n) { int i; for (i = 0; i < n->pos; i++) if (test_bit(i, n->used)) ip_set_ext_destroy(set, ahash_data(n, i, set->dsize)); } /* Flush a hash type of set: destroy all elements */ static void mtype_flush(struct ip_set *set) { struct htype *h = set->data; struct htable *t; struct hbucket *n; u32 r, i; t = ipset_dereference_nfnl(h->table); for (r = 0; r < ahash_numof_locks(t->htable_bits); r++) { spin_lock_bh(&t->hregion[r].lock); for (i = ahash_bucket_start(r, t->htable_bits); i < ahash_bucket_end(r, t->htable_bits); i++) { n = __ipset_dereference(hbucket(t, i)); if (!n) continue; if (set->extensions & IPSET_EXT_DESTROY) mtype_ext_cleanup(set, n); /* FIXME: use slab cache */ rcu_assign_pointer(hbucket(t, i), NULL); kfree_rcu(n, rcu); } t->hregion[r].ext_size = 0; t->hregion[r].elements = 0; spin_unlock_bh(&t->hregion[r].lock); } #ifdef IP_SET_HASH_WITH_NETS memset(h->nets, 0, sizeof(h->nets)); #endif } /* Destroy the hashtable part of the set */ static void mtype_ahash_destroy(struct ip_set *set, struct htable *t, bool ext_destroy) { struct hbucket *n; u32 i; for (i = 0; i < jhash_size(t->htable_bits); i++) { n = __ipset_dereference(hbucket(t, i)); if (!n) continue; if (set->extensions & IPSET_EXT_DESTROY && ext_destroy) mtype_ext_cleanup(set, n); /* FIXME: use slab cache */ kfree(n); } ip_set_free(t->hregion); ip_set_free(t); } /* Destroy a hash type of set */ static void mtype_destroy(struct ip_set *set) { struct htype *h = set->data; struct list_head *l, *lt; if (SET_WITH_TIMEOUT(set)) cancel_delayed_work_sync(&h->gc.dwork); mtype_ahash_destroy(set, ipset_dereference_nfnl(h->table), true); list_for_each_safe(l, lt, &h->ad) { list_del(l); kfree(l); } kfree(h); set->data = NULL; } static bool mtype_same_set(const struct ip_set *a, const struct ip_set *b) { const struct htype *x = a->data; const struct htype *y = b->data; /* Resizing changes htable_bits, so we ignore it */ return x->maxelem == y->maxelem && a->timeout == b->timeout && #ifdef IP_SET_HASH_WITH_NETMASK x->netmask == y->netmask && #endif #ifdef IP_SET_HASH_WITH_MARKMASK x->markmask == y->markmask && #endif a->extensions == b->extensions; } static void mtype_gc_do(struct ip_set *set, struct htype *h, struct htable *t, u32 r) { struct hbucket *n, *tmp; struct mtype_elem *data; u32 i, j, d; size_t dsize = set->dsize; #ifdef IP_SET_HASH_WITH_NETS u8 k; #endif u8 htable_bits = t->htable_bits; spin_lock_bh(&t->hregion[r].lock); for (i = ahash_bucket_start(r, htable_bits); i < ahash_bucket_end(r, htable_bits); i++) { n = __ipset_dereference(hbucket(t, i)); if (!n) continue; for (j = 0, d = 0; j < n->pos; j++) { if (!test_bit(j, n->used)) { d++; continue; } data = ahash_data(n, j, dsize); if (!ip_set_timeout_expired(ext_timeout(data, set))) continue; pr_debug("expired %u/%u\n", i, j); clear_bit(j, n->used); smp_mb__after_atomic(); #ifdef IP_SET_HASH_WITH_NETS for (k = 0; k < IPSET_NET_COUNT; k++) mtype_del_cidr(set, h, NCIDR_PUT(DCIDR_GET(data->cidr, k)), k); #endif t->hregion[r].elements--; ip_set_ext_destroy(set, data); d++; } if (d >= AHASH_INIT_SIZE) { if (d >= n->size) { t->hregion[r].ext_size -= ext_size(n->size, dsize); rcu_assign_pointer(hbucket(t, i), NULL); kfree_rcu(n, rcu); continue; } tmp = kzalloc(sizeof(*tmp) + (n->size - AHASH_INIT_SIZE) * dsize, GFP_ATOMIC); if (!tmp) /* Still try to delete expired elements. */ continue; tmp->size = n->size - AHASH_INIT_SIZE; for (j = 0, d = 0; j < n->pos; j++) { if (!test_bit(j, n->used)) continue; data = ahash_data(n, j, dsize); memcpy(tmp->value + d * dsize, data, dsize); set_bit(d, tmp->used); d++; } tmp->pos = d; t->hregion[r].ext_size -= ext_size(AHASH_INIT_SIZE, dsize); rcu_assign_pointer(hbucket(t, i), tmp); kfree_rcu(n, rcu); } } spin_unlock_bh(&t->hregion[r].lock); } static void mtype_gc(struct work_struct *work) { struct htable_gc *gc; struct ip_set *set; struct htype *h; struct htable *t; u32 r, numof_locks; unsigned int next_run; gc = container_of(work, struct htable_gc, dwork.work); set = gc->set; h = set->data; spin_lock_bh(&set->lock); t = ipset_dereference_set(h->table, set); atomic_inc(&t->uref); numof_locks = ahash_numof_locks(t->htable_bits); r = gc->region++; if (r >= numof_locks) { r = gc->region = 0; } next_run = (IPSET_GC_PERIOD(set->timeout) * HZ) / numof_locks; if (next_run < HZ/10) next_run = HZ/10; spin_unlock_bh(&set->lock); mtype_gc_do(set, h, t, r); if (atomic_dec_and_test(&t->uref) && atomic_read(&t->ref)) { pr_debug("Table destroy after resize by expire: %p\n", t); mtype_ahash_destroy(set, t, false); } queue_delayed_work(system_power_efficient_wq, &gc->dwork, next_run); } static void mtype_gc_init(struct htable_gc *gc) { INIT_DEFERRABLE_WORK(&gc->dwork, mtype_gc); queue_delayed_work(system_power_efficient_wq, &gc->dwork, HZ); } static int mtype_add(struct ip_set *set, void *value, const struct ip_set_ext *ext, struct ip_set_ext *mext, u32 flags); static int mtype_del(struct ip_set *set, void *value, const struct ip_set_ext *ext, struct ip_set_ext *mext, u32 flags); /* Resize a hash: create a new hash table with doubling the hashsize * and inserting the elements to it. Repeat until we succeed or * fail due to memory pressures. */ static int mtype_resize(struct ip_set *set, bool retried) { struct htype *h = set->data; struct htable *t, *orig; u8 htable_bits; size_t dsize = set->dsize; #ifdef IP_SET_HASH_WITH_NETS u8 flags; struct mtype_elem *tmp; #endif struct mtype_elem *data; struct mtype_elem *d; struct hbucket *n, *m; struct list_head *l, *lt; struct mtype_resize_ad *x; u32 i, j, r, nr, key; int ret; #ifdef IP_SET_HASH_WITH_NETS tmp = kmalloc(dsize, GFP_KERNEL); if (!tmp) return -ENOMEM; #endif orig = ipset_dereference_bh_nfnl(h->table); htable_bits = orig->htable_bits; retry: ret = 0; htable_bits++; if (!htable_bits) { /* In case we have plenty of memory :-) */ pr_warn("Cannot increase the hashsize of set %s further\n", set->name); ret = -IPSET_ERR_HASH_FULL; goto out; } t = ip_set_alloc(htable_size(htable_bits)); if (!t) { ret = -ENOMEM; goto out; } t->hregion = ip_set_alloc(ahash_sizeof_regions(htable_bits)); if (!t->hregion) { ip_set_free(t); ret = -ENOMEM; goto out; } t->htable_bits = htable_bits; t->maxelem = h->maxelem / ahash_numof_locks(htable_bits); for (i = 0; i < ahash_numof_locks(htable_bits); i++) spin_lock_init(&t->hregion[i].lock); /* There can't be another parallel resizing, * but dumping, gc, kernel side add/del are possible */ orig = ipset_dereference_bh_nfnl(h->table); atomic_set(&orig->ref, 1); atomic_inc(&orig->uref); pr_debug("attempt to resize set %s from %u to %u, t %p\n", set->name, orig->htable_bits, htable_bits, orig); for (r = 0; r < ahash_numof_locks(orig->htable_bits); r++) { /* Expire may replace a hbucket with another one */ rcu_read_lock_bh(); for (i = ahash_bucket_start(r, orig->htable_bits); i < ahash_bucket_end(r, orig->htable_bits); i++) { n = __ipset_dereference(hbucket(orig, i)); if (!n) continue; for (j = 0; j < n->pos; j++) { if (!test_bit(j, n->used)) continue; data = ahash_data(n, j, dsize); if (SET_ELEM_EXPIRED(set, data)) continue; #ifdef IP_SET_HASH_WITH_NETS /* We have readers running parallel with us, * so the live data cannot be modified. */ flags = 0; memcpy(tmp, data, dsize); data = tmp; mtype_data_reset_flags(data, &flags); #endif key = HKEY(data, h->initval, htable_bits); m = __ipset_dereference(hbucket(t, key)); nr = ahash_region(key, htable_bits); if (!m) { m = kzalloc(sizeof(*m) + AHASH_INIT_SIZE * dsize, GFP_ATOMIC); if (!m) { ret = -ENOMEM; goto cleanup; } m->size = AHASH_INIT_SIZE; t->hregion[nr].ext_size += ext_size(AHASH_INIT_SIZE, dsize); RCU_INIT_POINTER(hbucket(t, key), m); } else if (m->pos >= m->size) { struct hbucket *ht; if (m->size >= AHASH_MAX(h)) { ret = -EAGAIN; } else { ht = kzalloc(sizeof(*ht) + (m->size + AHASH_INIT_SIZE) * dsize, GFP_ATOMIC); if (!ht) ret = -ENOMEM; } if (ret < 0) goto cleanup; memcpy(ht, m, sizeof(struct hbucket) + m->size * dsize); ht->size = m->size + AHASH_INIT_SIZE; t->hregion[nr].ext_size += ext_size(AHASH_INIT_SIZE, dsize); kfree(m); m = ht; RCU_INIT_POINTER(hbucket(t, key), ht); } d = ahash_data(m, m->pos, dsize); memcpy(d, data, dsize); set_bit(m->pos++, m->used); t->hregion[nr].elements++; #ifdef IP_SET_HASH_WITH_NETS mtype_data_reset_flags(d, &flags); #endif } } rcu_read_unlock_bh(); } /* There can't be any other writer. */ rcu_assign_pointer(h->table, t); /* Give time to other readers of the set */ synchronize_rcu(); pr_debug("set %s resized from %u (%p) to %u (%p)\n", set->name, orig->htable_bits, orig, t->htable_bits, t); /* Add/delete elements processed by the SET target during resize. * Kernel-side add cannot trigger a resize and userspace actions * are serialized by the mutex. */ list_for_each_safe(l, lt, &h->ad) { x = list_entry(l, struct mtype_resize_ad, list); if (x->ad == IPSET_ADD) { mtype_add(set, &x->d, &x->ext, &x->mext, x->flags); } else { mtype_del(set, &x->d, NULL, NULL, 0); } list_del(l); kfree(l); } /* If there's nobody else using the table, destroy it */ if (atomic_dec_and_test(&orig->uref)) { pr_debug("Table destroy by resize %p\n", orig); mtype_ahash_destroy(set, orig, false); } out: #ifdef IP_SET_HASH_WITH_NETS kfree(tmp); #endif return ret; cleanup: rcu_read_unlock_bh(); atomic_set(&orig->ref, 0); atomic_dec(&orig->uref); mtype_ahash_destroy(set, t, false); if (ret == -EAGAIN) goto retry; goto out; } /* Get the current number of elements and ext_size in the set */ static void mtype_ext_size(struct ip_set *set, u32 *elements, size_t *ext_size) { struct htype *h = set->data; const struct htable *t; u32 i, j, r; struct hbucket *n; struct mtype_elem *data; *elements = 0; t = rcu_dereference_bh(h->table); for (r = 0; r < ahash_numof_locks(t->htable_bits); r++) { for (i = ahash_bucket_start(r, t->htable_bits); i < ahash_bucket_end(r, t->htable_bits); i++) { n = rcu_dereference_bh(hbucket(t, i)); if (!n) continue; for (j = 0; j < n->pos; j++) { if (!test_bit(j, n->used)) continue; data = ahash_data(n, j, set->dsize); if (!SET_ELEM_EXPIRED(set, data)) (*elements)++; } } *ext_size += t->hregion[r].ext_size; } } /* Add an element to a hash and update the internal counters when succeeded, * otherwise report the proper error code. */ static int mtype_add(struct ip_set *set, void *value, const struct ip_set_ext *ext, struct ip_set_ext *mext, u32 flags) { struct htype *h = set->data; struct htable *t; const struct mtype_elem *d = value; struct mtype_elem *data; struct hbucket *n, *old = ERR_PTR(-ENOENT); int i, j = -1, ret; bool flag_exist = flags & IPSET_FLAG_EXIST; bool deleted = false, forceadd = false, reuse = false; u32 r, key, multi = 0, elements, maxelem; rcu_read_lock_bh(); t = rcu_dereference_bh(h->table); key = HKEY(value, h->initval, t->htable_bits); r = ahash_region(key, t->htable_bits); atomic_inc(&t->uref); elements = t->hregion[r].elements; maxelem = t->maxelem; if (elements >= maxelem) { u32 e; if (SET_WITH_TIMEOUT(set)) { rcu_read_unlock_bh(); mtype_gc_do(set, h, t, r); rcu_read_lock_bh(); } maxelem = h->maxelem; elements = 0; for (e = 0; e < ahash_numof_locks(t->htable_bits); e++) elements += t->hregion[e].elements; if (elements >= maxelem && SET_WITH_FORCEADD(set)) forceadd = true; } rcu_read_unlock_bh(); spin_lock_bh(&t->hregion[r].lock); n = rcu_dereference_bh(hbucket(t, key)); if (!n) { if (forceadd || elements >= maxelem) goto set_full; old = NULL; n = kzalloc(sizeof(*n) + AHASH_INIT_SIZE * set->dsize, GFP_ATOMIC); if (!n) { ret = -ENOMEM; goto unlock; } n->size = AHASH_INIT_SIZE; t->hregion[r].ext_size += ext_size(AHASH_INIT_SIZE, set->dsize); goto copy_elem; } for (i = 0; i < n->pos; i++) { if (!test_bit(i, n->used)) { /* Reuse first deleted entry */ if (j == -1) { deleted = reuse = true; j = i; } continue; } data = ahash_data(n, i, set->dsize); if (mtype_data_equal(data, d, &multi)) { if (flag_exist || SET_ELEM_EXPIRED(set, data)) { /* Just the extensions could be overwritten */ j = i; goto overwrite_extensions; } ret = -IPSET_ERR_EXIST; goto unlock; } /* Reuse first timed out entry */ if (SET_ELEM_EXPIRED(set, data) && j == -1) { j = i; reuse = true; } } if (reuse || forceadd) { if (j == -1) j = 0; data = ahash_data(n, j, set->dsize); if (!deleted) { #ifdef IP_SET_HASH_WITH_NETS for (i = 0; i < IPSET_NET_COUNT; i++) mtype_del_cidr(set, h, NCIDR_PUT(DCIDR_GET(data->cidr, i)), i); #endif ip_set_ext_destroy(set, data); t->hregion[r].elements--; } goto copy_data; } if (elements >= maxelem) goto set_full; /* Create a new slot */ if (n->pos >= n->size) { TUNE_BUCKETSIZE(h, multi); if (n->size >= AHASH_MAX(h)) { /* Trigger rehashing */ mtype_data_next(&h->next, d); ret = -EAGAIN; goto resize; } old = n; n = kzalloc(sizeof(*n) + (old->size + AHASH_INIT_SIZE) * set->dsize, GFP_ATOMIC); if (!n) { ret = -ENOMEM; goto unlock; } memcpy(n, old, sizeof(struct hbucket) + old->size * set->dsize); n->size = old->size + AHASH_INIT_SIZE; t->hregion[r].ext_size += ext_size(AHASH_INIT_SIZE, set->dsize); } copy_elem: j = n->pos++; data = ahash_data(n, j, set->dsize); copy_data: t->hregion[r].elements++; #ifdef IP_SET_HASH_WITH_NETS for (i = 0; i < IPSET_NET_COUNT; i++) mtype_add_cidr(set, h, NCIDR_PUT(DCIDR_GET(d->cidr, i)), i); #endif memcpy(data, d, sizeof(struct mtype_elem)); overwrite_extensions: #ifdef IP_SET_HASH_WITH_NETS mtype_data_set_flags(data, flags); #endif if (SET_WITH_COUNTER(set)) ip_set_init_counter(ext_counter(data, set), ext); if (SET_WITH_COMMENT(set)) ip_set_init_comment(set, ext_comment(data, set), ext); if (SET_WITH_SKBINFO(set)) ip_set_init_skbinfo(ext_skbinfo(data, set), ext); /* Must come last for the case when timed out entry is reused */ if (SET_WITH_TIMEOUT(set)) ip_set_timeout_set(ext_timeout(data, set), ext->timeout); smp_mb__before_atomic(); set_bit(j, n->used); if (old != ERR_PTR(-ENOENT)) { rcu_assign_pointer(hbucket(t, key), n); if (old) kfree_rcu(old, rcu); } ret = 0; resize: spin_unlock_bh(&t->hregion[r].lock); if (atomic_read(&t->ref) && ext->target) { /* Resize is in process and kernel side add, save values */ struct mtype_resize_ad *x; x = kzalloc(sizeof(struct mtype_resize_ad), GFP_ATOMIC); if (!x) /* Don't bother */ goto out; x->ad = IPSET_ADD; memcpy(&x->d, value, sizeof(struct mtype_elem)); memcpy(&x->ext, ext, sizeof(struct ip_set_ext)); memcpy(&x->mext, mext, sizeof(struct ip_set_ext)); x->flags = flags; spin_lock_bh(&set->lock); list_add_tail(&x->list, &h->ad); spin_unlock_bh(&set->lock); } goto out; set_full: if (net_ratelimit()) pr_warn("Set %s is full, maxelem %u reached\n", set->name, maxelem); ret = -IPSET_ERR_HASH_FULL; unlock: spin_unlock_bh(&t->hregion[r].lock); out: if (atomic_dec_and_test(&t->uref) && atomic_read(&t->ref)) { pr_debug("Table destroy after resize by add: %p\n", t); mtype_ahash_destroy(set, t, false); } return ret; } /* Delete an element from the hash and free up space if possible. */ static int mtype_del(struct ip_set *set, void *value, const struct ip_set_ext *ext, struct ip_set_ext *mext, u32 flags) { struct htype *h = set->data; struct htable *t; const struct mtype_elem *d = value; struct mtype_elem *data; struct hbucket *n; struct mtype_resize_ad *x = NULL; int i, j, k, r, ret = -IPSET_ERR_EXIST; u32 key, multi = 0; size_t dsize = set->dsize; /* Userspace add and resize is excluded by the mutex. * Kernespace add does not trigger resize. */ rcu_read_lock_bh(); t = rcu_dereference_bh(h->table); key = HKEY(value, h->initval, t->htable_bits); r = ahash_region(key, t->htable_bits); atomic_inc(&t->uref); rcu_read_unlock_bh(); spin_lock_bh(&t->hregion[r].lock); n = rcu_dereference_bh(hbucket(t, key)); if (!n) goto out; for (i = 0, k = 0; i < n->pos; i++) { if (!test_bit(i, n->used)) { k++; continue; } data = ahash_data(n, i, dsize); if (!mtype_data_equal(data, d, &multi)) continue; if (SET_ELEM_EXPIRED(set, data)) goto out; ret = 0; clear_bit(i, n->used); smp_mb__after_atomic(); if (i + 1 == n->pos) n->pos--; t->hregion[r].elements--; #ifdef IP_SET_HASH_WITH_NETS for (j = 0; j < IPSET_NET_COUNT; j++) mtype_del_cidr(set, h, NCIDR_PUT(DCIDR_GET(d->cidr, j)), j); #endif ip_set_ext_destroy(set, data); if (atomic_read(&t->ref) && ext->target) { /* Resize is in process and kernel side del, * save values */ x = kzalloc(sizeof(struct mtype_resize_ad), GFP_ATOMIC); if (x) { x->ad = IPSET_DEL; memcpy(&x->d, value, sizeof(struct mtype_elem)); x->flags = flags; } } for (; i < n->pos; i++) { if (!test_bit(i, n->used)) k++; } if (n->pos == 0 && k == 0) { t->hregion[r].ext_size -= ext_size(n->size, dsize); rcu_assign_pointer(hbucket(t, key), NULL); kfree_rcu(n, rcu); } else if (k >= AHASH_INIT_SIZE) { struct hbucket *tmp = kzalloc(sizeof(*tmp) + (n->size - AHASH_INIT_SIZE) * dsize, GFP_ATOMIC); if (!tmp) goto out; tmp->size = n->size - AHASH_INIT_SIZE; for (j = 0, k = 0; j < n->pos; j++) { if (!test_bit(j, n->used)) continue; data = ahash_data(n, j, dsize); memcpy(tmp->value + k * dsize, data, dsize); set_bit(k, tmp->used); k++; } tmp->pos = k; t->hregion[r].ext_size -= ext_size(AHASH_INIT_SIZE, dsize); rcu_assign_pointer(hbucket(t, key), tmp); kfree_rcu(n, rcu); } goto out; } out: spin_unlock_bh(&t->hregion[r].lock); if (x) { spin_lock_bh(&set->lock); list_add(&x->list, &h->ad); spin_unlock_bh(&set->lock); } if (atomic_dec_and_test(&t->uref) && atomic_read(&t->ref)) { pr_debug("Table destroy after resize by del: %p\n", t); mtype_ahash_destroy(set, t, false); } return ret; } static int mtype_data_match(struct mtype_elem *data, const struct ip_set_ext *ext, struct ip_set_ext *mext, struct ip_set *set, u32 flags) { if (!ip_set_match_extensions(set, ext, mext, flags, data)) return 0; /* nomatch entries return -ENOTEMPTY */ return mtype_do_data_match(data); } #ifdef IP_SET_HASH_WITH_NETS /* Special test function which takes into account the different network * sizes added to the set */ static int mtype_test_cidrs(struct ip_set *set, struct mtype_elem *d, const struct ip_set_ext *ext, struct ip_set_ext *mext, u32 flags) { struct htype *h = set->data; struct htable *t = rcu_dereference_bh(h->table); struct hbucket *n; struct mtype_elem *data; #if IPSET_NET_COUNT == 2 struct mtype_elem orig = *d; int ret, i, j = 0, k; #else int ret, i, j = 0; #endif u32 key, multi = 0; pr_debug("test by nets\n"); for (; j < NLEN && h->nets[j].cidr[0] && !multi; j++) { #if IPSET_NET_COUNT == 2 mtype_data_reset_elem(d, &orig); mtype_data_netmask(d, NCIDR_GET(h->nets[j].cidr[0]), false); for (k = 0; k < NLEN && h->nets[k].cidr[1] && !multi; k++) { mtype_data_netmask(d, NCIDR_GET(h->nets[k].cidr[1]), true); #else mtype_data_netmask(d, NCIDR_GET(h->nets[j].cidr[0])); #endif key = HKEY(d, h->initval, t->htable_bits); n = rcu_dereference_bh(hbucket(t, key)); if (!n) continue; for (i = 0; i < n->pos; i++) { if (!test_bit(i, n->used)) continue; data = ahash_data(n, i, set->dsize); if (!mtype_data_equal(data, d, &multi)) continue; ret = mtype_data_match(data, ext, mext, set, flags); if (ret != 0) return ret; #ifdef IP_SET_HASH_WITH_MULTI /* No match, reset multiple match flag */ multi = 0; #endif } #if IPSET_NET_COUNT == 2 } #endif } return 0; } #endif /* Test whether the element is added to the set */ static int mtype_test(struct ip_set *set, void *value, const struct ip_set_ext *ext, struct ip_set_ext *mext, u32 flags) { struct htype *h = set->data; struct htable *t; struct mtype_elem *d = value; struct hbucket *n; struct mtype_elem *data; int i, ret = 0; u32 key, multi = 0; rcu_read_lock_bh(); t = rcu_dereference_bh(h->table); #ifdef IP_SET_HASH_WITH_NETS /* If we test an IP address and not a network address, * try all possible network sizes */ for (i = 0; i < IPSET_NET_COUNT; i++) if (DCIDR_GET(d->cidr, i) != HOST_MASK) break; if (i == IPSET_NET_COUNT) { ret = mtype_test_cidrs(set, d, ext, mext, flags); goto out; } #endif key = HKEY(d, h->initval, t->htable_bits); n = rcu_dereference_bh(hbucket(t, key)); if (!n) { ret = 0; goto out; } for (i = 0; i < n->pos; i++) { if (!test_bit(i, n->used)) continue; data = ahash_data(n, i, set->dsize); if (!mtype_data_equal(data, d, &multi)) continue; ret = mtype_data_match(data, ext, mext, set, flags); if (ret != 0) goto out; } out: rcu_read_unlock_bh(); return ret; } /* Reply a HEADER request: fill out the header part of the set */ static int mtype_head(struct ip_set *set, struct sk_buff *skb) { struct htype *h = set->data; const struct htable *t; struct nlattr *nested; size_t memsize; u32 elements = 0; size_t ext_size = 0; u8 htable_bits; rcu_read_lock_bh(); t = rcu_dereference_bh(h->table); mtype_ext_size(set, &elements, &ext_size); memsize = mtype_ahash_memsize(h, t) + ext_size + set->ext_size; htable_bits = t->htable_bits; rcu_read_unlock_bh(); nested = ipset_nest_start(skb, IPSET_ATTR_DATA); if (!nested) goto nla_put_failure; if (nla_put_net32(skb, IPSET_ATTR_HASHSIZE, htonl(jhash_size(htable_bits))) || nla_put_net32(skb, IPSET_ATTR_MAXELEM, htonl(h->maxelem))) goto nla_put_failure; #ifdef IP_SET_HASH_WITH_NETMASK if (h->netmask != HOST_MASK && nla_put_u8(skb, IPSET_ATTR_NETMASK, h->netmask)) goto nla_put_failure; #endif #ifdef IP_SET_HASH_WITH_MARKMASK if (nla_put_u32(skb, IPSET_ATTR_MARKMASK, h->markmask)) goto nla_put_failure; #endif if (set->flags & IPSET_CREATE_FLAG_BUCKETSIZE) { if (nla_put_u8(skb, IPSET_ATTR_BUCKETSIZE, h->bucketsize) || nla_put_net32(skb, IPSET_ATTR_INITVAL, htonl(h->initval))) goto nla_put_failure; } if (nla_put_net32(skb, IPSET_ATTR_REFERENCES, htonl(set->ref)) || nla_put_net32(skb, IPSET_ATTR_MEMSIZE, htonl(memsize)) || nla_put_net32(skb, IPSET_ATTR_ELEMENTS, htonl(elements))) goto nla_put_failure; if (unlikely(ip_set_put_flags(skb, set))) goto nla_put_failure; ipset_nest_end(skb, nested); return 0; nla_put_failure: return -EMSGSIZE; } /* Make possible to run dumping parallel with resizing */ static void mtype_uref(struct ip_set *set, struct netlink_callback *cb, bool start) { struct htype *h = set->data; struct htable *t; if (start) { rcu_read_lock_bh(); t = ipset_dereference_bh_nfnl(h->table); atomic_inc(&t->uref); cb->args[IPSET_CB_PRIVATE] = (unsigned long)t; rcu_read_unlock_bh(); } else if (cb->args[IPSET_CB_PRIVATE]) { t = (struct htable *)cb->args[IPSET_CB_PRIVATE]; if (atomic_dec_and_test(&t->uref) && atomic_read(&t->ref)) { pr_debug("Table destroy after resize " " by dump: %p\n", t); mtype_ahash_destroy(set, t, false); } cb->args[IPSET_CB_PRIVATE] = 0; } } /* Reply a LIST/SAVE request: dump the elements of the specified set */ static int mtype_list(const struct ip_set *set, struct sk_buff *skb, struct netlink_callback *cb) { const struct htable *t; struct nlattr *atd, *nested; const struct hbucket *n; const struct mtype_elem *e; u32 first = cb->args[IPSET_CB_ARG0]; /* We assume that one hash bucket fills into one page */ void *incomplete; int i, ret = 0; atd = ipset_nest_start(skb, IPSET_ATTR_ADT); if (!atd) return -EMSGSIZE; pr_debug("list hash set %s\n", set->name); t = (const struct htable *)cb->args[IPSET_CB_PRIVATE]; /* Expire may replace a hbucket with another one */ rcu_read_lock(); for (; cb->args[IPSET_CB_ARG0] < jhash_size(t->htable_bits); cb->args[IPSET_CB_ARG0]++) { cond_resched_rcu(); incomplete = skb_tail_pointer(skb); n = rcu_dereference(hbucket(t, cb->args[IPSET_CB_ARG0])); pr_debug("cb->arg bucket: %lu, t %p n %p\n", cb->args[IPSET_CB_ARG0], t, n); if (!n) continue; for (i = 0; i < n->pos; i++) { if (!test_bit(i, n->used)) continue; e = ahash_data(n, i, set->dsize); if (SET_ELEM_EXPIRED(set, e)) continue; pr_debug("list hash %lu hbucket %p i %u, data %p\n", cb->args[IPSET_CB_ARG0], n, i, e); nested = ipset_nest_start(skb, IPSET_ATTR_DATA); if (!nested) { if (cb->args[IPSET_CB_ARG0] == first) { nla_nest_cancel(skb, atd); ret = -EMSGSIZE; goto out; } goto nla_put_failure; } if (mtype_data_list(skb, e)) goto nla_put_failure; if (ip_set_put_extensions(skb, set, e, true)) goto nla_put_failure; ipset_nest_end(skb, nested); } } ipset_nest_end(skb, atd); /* Set listing finished */ cb->args[IPSET_CB_ARG0] = 0; goto out; nla_put_failure: nlmsg_trim(skb, incomplete); if (unlikely(first == cb->args[IPSET_CB_ARG0])) { pr_warn("Can't list set %s: one bucket does not fit into a message. Please report it!\n", set->name); cb->args[IPSET_CB_ARG0] = 0; ret = -EMSGSIZE; } else { ipset_nest_end(skb, atd); } out: rcu_read_unlock(); return ret; } static int IPSET_TOKEN(MTYPE, _kadt)(struct ip_set *set, const struct sk_buff *skb, const struct xt_action_param *par, enum ipset_adt adt, struct ip_set_adt_opt *opt); static int IPSET_TOKEN(MTYPE, _uadt)(struct ip_set *set, struct nlattr *tb[], enum ipset_adt adt, u32 *lineno, u32 flags, bool retried); static const struct ip_set_type_variant mtype_variant = { .kadt = mtype_kadt, .uadt = mtype_uadt, .adt = { [IPSET_ADD] = mtype_add, [IPSET_DEL] = mtype_del, [IPSET_TEST] = mtype_test, }, .destroy = mtype_destroy, .flush = mtype_flush, .head = mtype_head, .list = mtype_list, .uref = mtype_uref, .resize = mtype_resize, .same_set = mtype_same_set, .region_lock = true, }; #ifdef IP_SET_EMIT_CREATE static int IPSET_TOKEN(HTYPE, _create)(struct net *net, struct ip_set *set, struct nlattr *tb[], u32 flags) { u32 hashsize = IPSET_DEFAULT_HASHSIZE, maxelem = IPSET_DEFAULT_MAXELEM; #ifdef IP_SET_HASH_WITH_MARKMASK u32 markmask; #endif u8 hbits; #ifdef IP_SET_HASH_WITH_NETMASK u8 netmask; #endif size_t hsize; struct htype *h; struct htable *t; u32 i; pr_debug("Create set %s with family %s\n", set->name, set->family == NFPROTO_IPV4 ? "inet" : "inet6"); #ifdef IP_SET_PROTO_UNDEF if (set->family != NFPROTO_UNSPEC) return -IPSET_ERR_INVALID_FAMILY; #else if (!(set->family == NFPROTO_IPV4 || set->family == NFPROTO_IPV6)) return -IPSET_ERR_INVALID_FAMILY; #endif if (unlikely(!ip_set_optattr_netorder(tb, IPSET_ATTR_HASHSIZE) || !ip_set_optattr_netorder(tb, IPSET_ATTR_MAXELEM) || !ip_set_optattr_netorder(tb, IPSET_ATTR_TIMEOUT) || !ip_set_optattr_netorder(tb, IPSET_ATTR_CADT_FLAGS))) return -IPSET_ERR_PROTOCOL; #ifdef IP_SET_HASH_WITH_MARKMASK /* Separated condition in order to avoid directive in argument list */ if (unlikely(!ip_set_optattr_netorder(tb, IPSET_ATTR_MARKMASK))) return -IPSET_ERR_PROTOCOL; markmask = 0xffffffff; if (tb[IPSET_ATTR_MARKMASK]) { markmask = ntohl(nla_get_be32(tb[IPSET_ATTR_MARKMASK])); if (markmask == 0) return -IPSET_ERR_INVALID_MARKMASK; } #endif #ifdef IP_SET_HASH_WITH_NETMASK netmask = set->family == NFPROTO_IPV4 ? 32 : 128; if (tb[IPSET_ATTR_NETMASK]) { netmask = nla_get_u8(tb[IPSET_ATTR_NETMASK]); if ((set->family == NFPROTO_IPV4 && netmask > 32) || (set->family == NFPROTO_IPV6 && netmask > 128) || netmask == 0) return -IPSET_ERR_INVALID_NETMASK; } #endif if (tb[IPSET_ATTR_HASHSIZE]) { hashsize = ip_set_get_h32(tb[IPSET_ATTR_HASHSIZE]); if (hashsize < IPSET_MIMINAL_HASHSIZE) hashsize = IPSET_MIMINAL_HASHSIZE; } if (tb[IPSET_ATTR_MAXELEM]) maxelem = ip_set_get_h32(tb[IPSET_ATTR_MAXELEM]); hsize = sizeof(*h); h = kzalloc(hsize, GFP_KERNEL); if (!h) return -ENOMEM; hbits = htable_bits(hashsize); hsize = htable_size(hbits); if (hsize == 0) { kfree(h); return -ENOMEM; } t = ip_set_alloc(hsize); if (!t) { kfree(h); return -ENOMEM; } t->hregion = ip_set_alloc(ahash_sizeof_regions(hbits)); if (!t->hregion) { ip_set_free(t); kfree(h); return -ENOMEM; } h->gc.set = set; for (i = 0; i < ahash_numof_locks(hbits); i++) spin_lock_init(&t->hregion[i].lock); h->maxelem = maxelem; #ifdef IP_SET_HASH_WITH_NETMASK h->netmask = netmask; #endif #ifdef IP_SET_HASH_WITH_MARKMASK h->markmask = markmask; #endif if (tb[IPSET_ATTR_INITVAL]) h->initval = ntohl(nla_get_be32(tb[IPSET_ATTR_INITVAL])); else get_random_bytes(&h->initval, sizeof(h->initval)); h->bucketsize = AHASH_MAX_SIZE; if (tb[IPSET_ATTR_BUCKETSIZE]) { h->bucketsize = nla_get_u8(tb[IPSET_ATTR_BUCKETSIZE]); if (h->bucketsize < AHASH_INIT_SIZE) h->bucketsize = AHASH_INIT_SIZE; else if (h->bucketsize > AHASH_MAX_SIZE) h->bucketsize = AHASH_MAX_SIZE; else if (h->bucketsize % 2) h->bucketsize += 1; } t->htable_bits = hbits; t->maxelem = h->maxelem / ahash_numof_locks(hbits); RCU_INIT_POINTER(h->table, t); INIT_LIST_HEAD(&h->ad); set->data = h; #ifndef IP_SET_PROTO_UNDEF if (set->family == NFPROTO_IPV4) { #endif set->variant = &IPSET_TOKEN(HTYPE, 4_variant); set->dsize = ip_set_elem_len(set, tb, sizeof(struct IPSET_TOKEN(HTYPE, 4_elem)), __alignof__(struct IPSET_TOKEN(HTYPE, 4_elem))); #ifndef IP_SET_PROTO_UNDEF } else { set->variant = &IPSET_TOKEN(HTYPE, 6_variant); set->dsize = ip_set_elem_len(set, tb, sizeof(struct IPSET_TOKEN(HTYPE, 6_elem)), __alignof__(struct IPSET_TOKEN(HTYPE, 6_elem))); } #endif set->timeout = IPSET_NO_TIMEOUT; if (tb[IPSET_ATTR_TIMEOUT]) { set->timeout = ip_set_timeout_uget(tb[IPSET_ATTR_TIMEOUT]); #ifndef IP_SET_PROTO_UNDEF if (set->family == NFPROTO_IPV4) #endif IPSET_TOKEN(HTYPE, 4_gc_init)(&h->gc); #ifndef IP_SET_PROTO_UNDEF else IPSET_TOKEN(HTYPE, 6_gc_init)(&h->gc); #endif } pr_debug("create %s hashsize %u (%u) maxelem %u: %p(%p)\n", set->name, jhash_size(t->htable_bits), t->htable_bits, h->maxelem, set->data, t); return 0; } #endif /* IP_SET_EMIT_CREATE */ #undef HKEY_DATALEN