/*****************************************************************************\ * Copyright (C) 2010 Lawrence Livermore National Security, LLC. * Produced at Lawrence Livermore National Laboratory (cf, DISCLAIMER). * Written by Brian Behlendorf . * UCRL-CODE-235197 * * This file is part of the SPL, Solaris Porting Layer. * For details, see . * * The SPL is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation; either version 2 of the License, or (at your * option) any later version. * * The SPL is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * for more details. * * You should have received a copy of the GNU General Public License along * with the SPL. If not, see . ***************************************************************************** * Solaris Porting Layer (SPL) Thread Specific Data Implementation. * * Thread specific data has implemented using a hash table, this avoids * the need to add a member to the task structure and allows maximum * portability between kernels. This implementation has been optimized * to keep the tsd_set() and tsd_get() times as small as possible. * * The majority of the entries in the hash table are for specific tsd * entries. These entries are hashed by the product of their key and * pid because by design the key and pid are guaranteed to be unique. * Their product also has the desirable properly that it will be uniformly * distributed over the hash bins providing neither the pid nor key is zero. * Under linux the zero pid is always the init process and thus won't be * used, and this implementation is careful to never to assign a zero key. * By default the hash table is sized to 512 bins which is expected to * be sufficient for light to moderate usage of thread specific data. * * The hash table contains two additional type of entries. They first * type is entry is called a 'key' entry and it is added to the hash during * tsd_create(). It is used to store the address of the destructor function * and it is used as an anchor point. All tsd entries which use the same * key will be linked to this entry. This is used during tsd_destory() to * quickly call the destructor function for all tsd associated with the key. * The 'key' entry may be looked up with tsd_hash_search() by passing the * key you wish to lookup and DTOR_PID constant as the pid. * * The second type of entry is called a 'pid' entry and it is added to the * hash the first time a process set a key. The 'pid' entry is also used * as an anchor and all tsd for the process will be linked to it. This * list is using during tsd_exit() to ensure all registered destructors * are run for the process. The 'pid' entry may be looked up with * tsd_hash_search() by passing the PID_KEY constant as the key, and * the process pid. Note that tsd_exit() is called by thread_exit() * so if your using the Solaris thread API you should not need to call * tsd_exit() directly. * \*****************************************************************************/ #include #include #include #include typedef struct tsd_hash_bin { spinlock_t hb_lock; struct hlist_head hb_head; } tsd_hash_bin_t; typedef struct tsd_hash_table { spinlock_t ht_lock; uint_t ht_bits; uint_t ht_key; tsd_hash_bin_t *ht_bins; } tsd_hash_table_t; typedef struct tsd_hash_entry { uint_t he_key; pid_t he_pid; dtor_func_t he_dtor; void *he_value; struct hlist_node he_list; struct list_head he_key_list; struct list_head he_pid_list; } tsd_hash_entry_t; static tsd_hash_table_t *tsd_hash_table = NULL; /* * tsd_hash_search - searches hash table for tsd_hash_entry * @table: hash table * @key: search key * @pid: search pid */ static tsd_hash_entry_t * tsd_hash_search(tsd_hash_table_t *table, uint_t key, pid_t pid) { struct hlist_node *node; tsd_hash_entry_t *entry; tsd_hash_bin_t *bin; ulong_t hash; hash = hash_long((ulong_t)key * (ulong_t)pid, table->ht_bits); bin = &table->ht_bins[hash]; spin_lock(&bin->hb_lock); hlist_for_each(node, &bin->hb_head) { entry = list_entry(node, tsd_hash_entry_t, he_list); if ((entry->he_key == key) && (entry->he_pid == pid)) { spin_unlock(&bin->hb_lock); return (entry); } } spin_unlock(&bin->hb_lock); return (NULL); } /* * tsd_hash_dtor - call the destructor and free all entries on the list * @work: list of hash entries * * For a list of entries which have all already been removed from the * hash call their registered destructor then free the associated memory. */ static void tsd_hash_dtor(struct hlist_head *work) { tsd_hash_entry_t *entry; while (!hlist_empty(work)) { entry = hlist_entry(work->first, tsd_hash_entry_t, he_list); hlist_del(&entry->he_list); if (entry->he_dtor && entry->he_pid != DTOR_PID) entry->he_dtor(entry->he_value); kmem_free(entry, sizeof(tsd_hash_entry_t)); } } /* * tsd_hash_add - adds an entry to hash table * @table: hash table * @key: search key * @pid: search pid * * The caller is responsible for ensuring the unique key/pid do not * already exist in the hash table. This possible because all entries * are thread specific thus a concurrent thread will never attempt to * add this key/pid. Because multiple bins must be checked to add * links to the dtor and pid entries the entire table is locked. */ static int tsd_hash_add(tsd_hash_table_t *table, uint_t key, pid_t pid, void *value) { tsd_hash_entry_t *entry, *dtor_entry, *pid_entry; tsd_hash_bin_t *bin; ulong_t hash; int rc = 0; ASSERT3P(tsd_hash_search(table, key, pid), ==, NULL); /* New entry allocate structure, set value, and add to hash */ entry = kmem_alloc(sizeof(tsd_hash_entry_t), KM_PUSHPAGE); if (entry == NULL) return (ENOMEM); entry->he_key = key; entry->he_pid = pid; entry->he_value = value; INIT_HLIST_NODE(&entry->he_list); INIT_LIST_HEAD(&entry->he_key_list); INIT_LIST_HEAD(&entry->he_pid_list); spin_lock(&table->ht_lock); /* Destructor entry must exist for all valid keys */ dtor_entry = tsd_hash_search(table, entry->he_key, DTOR_PID); ASSERT3P(dtor_entry, !=, NULL); entry->he_dtor = dtor_entry->he_dtor; /* Process entry must exist for all valid processes */ pid_entry = tsd_hash_search(table, PID_KEY, entry->he_pid); ASSERT3P(pid_entry, !=, NULL); hash = hash_long((ulong_t)key * (ulong_t)pid, table->ht_bits); bin = &table->ht_bins[hash]; spin_lock(&bin->hb_lock); /* Add to the hash, key, and pid lists */ hlist_add_head(&entry->he_list, &bin->hb_head); list_add(&entry->he_key_list, &dtor_entry->he_key_list); list_add(&entry->he_pid_list, &pid_entry->he_pid_list); spin_unlock(&bin->hb_lock); spin_unlock(&table->ht_lock); return (rc); } /* * tsd_hash_add_key - adds a destructor entry to the hash table * @table: hash table * @keyp: search key * @dtor: key destructor * * For every unique key there is a single entry in the hash which is used * as anchor. All other thread specific entries for this key are linked * to this anchor via the 'he_key_list' list head. On return they keyp * will be set to the next available key for the hash table. */ static int tsd_hash_add_key(tsd_hash_table_t *table, uint_t *keyp, dtor_func_t dtor) { tsd_hash_entry_t *tmp_entry, *entry; tsd_hash_bin_t *bin; ulong_t hash; int keys_checked = 0; ASSERT3P(table, !=, NULL); /* Allocate entry to be used as a destructor for this key */ entry = kmem_alloc(sizeof(tsd_hash_entry_t), KM_PUSHPAGE); if (entry == NULL) return (ENOMEM); /* Determine next available key value */ spin_lock(&table->ht_lock); do { /* Limited to TSD_KEYS_MAX concurrent unique keys */ if (table->ht_key++ > TSD_KEYS_MAX) table->ht_key = 1; /* Ensure failure when all TSD_KEYS_MAX keys are in use */ if (keys_checked++ >= TSD_KEYS_MAX) { spin_unlock(&table->ht_lock); return (ENOENT); } tmp_entry = tsd_hash_search(table, table->ht_key, DTOR_PID); } while (tmp_entry); /* Add destructor entry in to hash table */ entry->he_key = *keyp = table->ht_key; entry->he_pid = DTOR_PID; entry->he_dtor = dtor; entry->he_value = NULL; INIT_HLIST_NODE(&entry->he_list); INIT_LIST_HEAD(&entry->he_key_list); INIT_LIST_HEAD(&entry->he_pid_list); hash = hash_long((ulong_t)*keyp * (ulong_t)DTOR_PID, table->ht_bits); bin = &table->ht_bins[hash]; spin_lock(&bin->hb_lock); hlist_add_head(&entry->he_list, &bin->hb_head); spin_unlock(&bin->hb_lock); spin_unlock(&table->ht_lock); return (0); } /* * tsd_hash_add_pid - adds a process entry to the hash table * @table: hash table * @pid: search pid * * For every process these is a single entry in the hash which is used * as anchor. All other thread specific entries for this process are * linked to this anchor via the 'he_pid_list' list head. */ static int tsd_hash_add_pid(tsd_hash_table_t *table, pid_t pid) { tsd_hash_entry_t *entry; tsd_hash_bin_t *bin; ulong_t hash; /* Allocate entry to be used as the process reference */ entry = kmem_alloc(sizeof(tsd_hash_entry_t), KM_PUSHPAGE); if (entry == NULL) return (ENOMEM); spin_lock(&table->ht_lock); entry->he_key = PID_KEY; entry->he_pid = pid; entry->he_dtor = NULL; entry->he_value = NULL; INIT_HLIST_NODE(&entry->he_list); INIT_LIST_HEAD(&entry->he_key_list); INIT_LIST_HEAD(&entry->he_pid_list); hash = hash_long((ulong_t)PID_KEY * (ulong_t)pid, table->ht_bits); bin = &table->ht_bins[hash]; spin_lock(&bin->hb_lock); hlist_add_head(&entry->he_list, &bin->hb_head); spin_unlock(&bin->hb_lock); spin_unlock(&table->ht_lock); return (0); } /* * tsd_hash_del - delete an entry from hash table, key, and pid lists * @table: hash table * @key: search key * @pid: search pid */ static void tsd_hash_del(tsd_hash_table_t *table, tsd_hash_entry_t *entry) { ASSERT(spin_is_locked(&table->ht_lock)); hlist_del(&entry->he_list); list_del_init(&entry->he_key_list); list_del_init(&entry->he_pid_list); } /* * tsd_hash_table_init - allocate a hash table * @bits: hash table size * * A hash table with 2^bits bins will be created, it may not be resized * after the fact and must be free'd with tsd_hash_table_fini(). */ static tsd_hash_table_t * tsd_hash_table_init(uint_t bits) { tsd_hash_table_t *table; int hash, size = (1 << bits); table = kmem_zalloc(sizeof(tsd_hash_table_t), KM_SLEEP); if (table == NULL) return (NULL); table->ht_bins = kmem_zalloc(sizeof(tsd_hash_bin_t) * size, KM_SLEEP); if (table->ht_bins == NULL) { kmem_free(table, sizeof(tsd_hash_table_t)); return (NULL); } for (hash = 0; hash < size; hash++) { spin_lock_init(&table->ht_bins[hash].hb_lock); INIT_HLIST_HEAD(&table->ht_bins[hash].hb_head); } spin_lock_init(&table->ht_lock); table->ht_bits = bits; table->ht_key = 1; return (table); } /* * tsd_hash_table_fini - free a hash table * @table: hash table * * Free a hash table allocated by tsd_hash_table_init(). If the hash * table is not empty this function will call the proper destructor for * all remaining entries before freeing the memory used by those entries. */ static void tsd_hash_table_fini(tsd_hash_table_t *table) { HLIST_HEAD(work); tsd_hash_bin_t *bin; tsd_hash_entry_t *entry; int size, i; ASSERT3P(table, !=, NULL); spin_lock(&table->ht_lock); for (i = 0, size = (1 << table->ht_bits); i < size; i++) { bin = &table->ht_bins[i]; spin_lock(&bin->hb_lock); while (!hlist_empty(&bin->hb_head)) { entry = hlist_entry(bin->hb_head.first, tsd_hash_entry_t, he_list); tsd_hash_del(table, entry); hlist_add_head(&entry->he_list, &work); } spin_unlock(&bin->hb_lock); } spin_unlock(&table->ht_lock); tsd_hash_dtor(&work); kmem_free(table->ht_bins, sizeof(tsd_hash_bin_t)*(1<ht_bits)); kmem_free(table, sizeof(tsd_hash_table_t)); } /* * tsd_set - set thread specific data * @key: lookup key * @value: value to set * * Caller must prevent racing tsd_create() or tsd_destroy(), protected * from racing tsd_get() or tsd_set() because it is thread specific. * This function has been optimized to be fast for the update case. * When setting the tsd initially it will be slower due to additional * required locking and potential memory allocations. */ int tsd_set(uint_t key, void *value) { tsd_hash_table_t *table; tsd_hash_entry_t *entry; pid_t pid; int rc; table = tsd_hash_table; pid = curthread->pid; ASSERT3P(table, !=, NULL); if ((key == 0) || (key > TSD_KEYS_MAX)) return (EINVAL); /* Entry already exists in hash table update value */ entry = tsd_hash_search(table, key, pid); if (entry) { entry->he_value = value; return (0); } /* Add a process entry to the hash if not yet exists */ entry = tsd_hash_search(table, PID_KEY, pid); if (entry == NULL) { rc = tsd_hash_add_pid(table, pid); if (rc) return (rc); } rc = tsd_hash_add(table, key, pid, value); return (rc); } EXPORT_SYMBOL(tsd_set); /* * tsd_get - get thread specific data * @key: lookup key * * Caller must prevent racing tsd_create() or tsd_destroy(). This * implementation is designed to be fast and scalable, it does not * lock the entire table only a single hash bin. */ void * tsd_get(uint_t key) { tsd_hash_entry_t *entry; ASSERT3P(tsd_hash_table, !=, NULL); if ((key == 0) || (key > TSD_KEYS_MAX)) return (NULL); entry = tsd_hash_search(tsd_hash_table, key, curthread->pid); if (entry == NULL) return (NULL); return (entry->he_value); } EXPORT_SYMBOL(tsd_get); /* * tsd_create - create thread specific data key * @keyp: lookup key address * @dtor: destructor called during tsd_destroy() or tsd_exit() * * Provided key must be set to 0 or it assumed to be already in use. * The dtor is allowed to be NULL in which case no additional cleanup * for the data is performed during tsd_destroy() or tsd_exit(). * * Caller must prevent racing tsd_set() or tsd_get(), this function is * safe from racing tsd_create(), tsd_destroy(), and tsd_exit(). */ void tsd_create(uint_t *keyp, dtor_func_t dtor) { ASSERT3P(keyp, !=, NULL); if (*keyp) return; (void)tsd_hash_add_key(tsd_hash_table, keyp, dtor); } EXPORT_SYMBOL(tsd_create); /* * tsd_destroy - destroy thread specific data * @keyp: lookup key address * * Destroys the thread specific data on all threads which use this key. * * Caller must prevent racing tsd_set() or tsd_get(), this function is * safe from racing tsd_create(), tsd_destroy(), and tsd_exit(). */ void tsd_destroy(uint_t *keyp) { HLIST_HEAD(work); tsd_hash_table_t *table; tsd_hash_entry_t *dtor_entry, *entry; tsd_hash_bin_t *dtor_entry_bin, *entry_bin; ulong_t hash; table = tsd_hash_table; ASSERT3P(table, !=, NULL); spin_lock(&table->ht_lock); dtor_entry = tsd_hash_search(table, *keyp, DTOR_PID); if (dtor_entry == NULL) { spin_unlock(&table->ht_lock); return; } /* * All threads which use this key must be linked off of the * DTOR_PID entry. They are removed from the hash table and * linked in to a private working list to be destroyed. */ while (!list_empty(&dtor_entry->he_key_list)) { entry = list_entry(dtor_entry->he_key_list.next, tsd_hash_entry_t, he_key_list); ASSERT3U(dtor_entry->he_key, ==, entry->he_key); ASSERT3P(dtor_entry->he_dtor, ==, entry->he_dtor); hash = hash_long((ulong_t)entry->he_key * (ulong_t)entry->he_pid, table->ht_bits); entry_bin = &table->ht_bins[hash]; spin_lock(&entry_bin->hb_lock); tsd_hash_del(table, entry); hlist_add_head(&entry->he_list, &work); spin_unlock(&entry_bin->hb_lock); } hash = hash_long((ulong_t)dtor_entry->he_key * (ulong_t)dtor_entry->he_pid, table->ht_bits); dtor_entry_bin = &table->ht_bins[hash]; spin_lock(&dtor_entry_bin->hb_lock); tsd_hash_del(table, dtor_entry); hlist_add_head(&dtor_entry->he_list, &work); spin_unlock(&dtor_entry_bin->hb_lock); spin_unlock(&table->ht_lock); tsd_hash_dtor(&work); *keyp = 0; } EXPORT_SYMBOL(tsd_destroy); /* * tsd_exit - destroys all thread specific data for this thread * * Destroys all the thread specific data for this thread. * * Caller must prevent racing tsd_set() or tsd_get(), this function is * safe from racing tsd_create(), tsd_destroy(), and tsd_exit(). */ void tsd_exit(void) { HLIST_HEAD(work); tsd_hash_table_t *table; tsd_hash_entry_t *pid_entry, *entry; tsd_hash_bin_t *pid_entry_bin, *entry_bin; ulong_t hash; table = tsd_hash_table; ASSERT3P(table, !=, NULL); spin_lock(&table->ht_lock); pid_entry = tsd_hash_search(table, PID_KEY, curthread->pid); if (pid_entry == NULL) { spin_unlock(&table->ht_lock); return; } /* * All keys associated with this pid must be linked off of the * PID_KEY entry. They are removed from the hash table and * linked in to a private working list to be destroyed. */ while (!list_empty(&pid_entry->he_pid_list)) { entry = list_entry(pid_entry->he_pid_list.next, tsd_hash_entry_t, he_pid_list); ASSERT3U(pid_entry->he_pid, ==, entry->he_pid); hash = hash_long((ulong_t)entry->he_key * (ulong_t)entry->he_pid, table->ht_bits); entry_bin = &table->ht_bins[hash]; spin_lock(&entry_bin->hb_lock); tsd_hash_del(table, entry); hlist_add_head(&entry->he_list, &work); spin_unlock(&entry_bin->hb_lock); } hash = hash_long((ulong_t)pid_entry->he_key * (ulong_t)pid_entry->he_pid, table->ht_bits); pid_entry_bin = &table->ht_bins[hash]; spin_lock(&pid_entry_bin->hb_lock); tsd_hash_del(table, pid_entry); hlist_add_head(&pid_entry->he_list, &work); spin_unlock(&pid_entry_bin->hb_lock); spin_unlock(&table->ht_lock); tsd_hash_dtor(&work); } EXPORT_SYMBOL(tsd_exit); int spl_tsd_init(void) { tsd_hash_table = tsd_hash_table_init(TSD_HASH_TABLE_BITS_DEFAULT); if (tsd_hash_table == NULL) return (1); return (0); } void spl_tsd_fini(void) { tsd_hash_table_fini(tsd_hash_table); tsd_hash_table = NULL; }