/* Copyright (c) 2000, 2011, Oracle and/or its affiliates This program 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; version 2 of the License. This program 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 this program; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #ifdef USE_PRAGMA_IMPLEMENTATION #pragma implementation // gcc: Class implementation #endif #define MYSQL_SERVER 1 #include #include "sql_priv.h" #include "sql_plugin.h" #include "ha_heap.h" #include "heapdef.h" #include "sql_base.h" // enum_tdc_remove_table_type static handler *heap_create_handler(handlerton *hton, TABLE_SHARE *table, MEM_ROOT *mem_root); static int heap_prepare_hp_create_info(TABLE *table_arg, bool internal_table, HP_CREATE_INFO *hp_create_info); int heap_panic(handlerton *hton, ha_panic_function flag) { return hp_panic(flag); } int heap_init(void *p) { handlerton *heap_hton; #ifdef HAVE_PSI_INTERFACE init_heap_psi_keys(); #endif heap_hton= (handlerton *)p; heap_hton->state= SHOW_OPTION_YES; heap_hton->db_type= DB_TYPE_HEAP; heap_hton->create= heap_create_handler; heap_hton->panic= heap_panic; heap_hton->flags= HTON_CAN_RECREATE; return 0; } static handler *heap_create_handler(handlerton *hton, TABLE_SHARE *table, MEM_ROOT *mem_root) { return new (mem_root) ha_heap(hton, table); } /***************************************************************************** ** HEAP tables *****************************************************************************/ ha_heap::ha_heap(handlerton *hton, TABLE_SHARE *table_arg) :handler(hton, table_arg), file(0), records_changed(0), key_stat_version(0), internal_table(0) {} /* Hash index statistics is updated (copied from HP_KEYDEF::hash_buckets to rec_per_key) after 1/HEAP_STATS_UPDATE_THRESHOLD fraction of table records have been inserted/updated/deleted. delete_all_rows() and table flush cause immediate update. NOTE hash index statistics must be updated when number of table records changes from 0 to non-zero value and vice versa. Otherwise records_in_range may erroneously return 0 and 'range' may miss records. */ #define HEAP_STATS_UPDATE_THRESHOLD 10 int ha_heap::open(const char *name, int mode, uint test_if_locked) { internal_table= MY_TEST(test_if_locked & HA_OPEN_INTERNAL_TABLE); if (internal_table || (!(file= heap_open(name, mode)) && my_errno == ENOENT)) { HP_CREATE_INFO create_info; my_bool created_new_share; int rc; file= 0; if (heap_prepare_hp_create_info(table, internal_table, &create_info)) goto end; create_info.pin_share= TRUE; rc= heap_create(name, &create_info, &internal_share, &created_new_share); my_free(create_info.keydef); if (rc) goto end; implicit_emptied= MY_TEST(created_new_share); if (internal_table) file= heap_open_from_share(internal_share, mode); else file= heap_open_from_share_and_register(internal_share, mode); if (!file) { heap_release_share(internal_share, internal_table); goto end; } } ref_length= sizeof(HEAP_PTR); /* Initialize variables for the opened table */ set_keys_for_scanning(); /* We cannot run update_key_stats() here because we do not have a lock on the table. The 'records' count might just be changed temporarily at this moment and we might get wrong statistics (Bug #10178). Instead we request for update. This will be done in ha_heap::info(), which is always called before key statistics are used. */ key_stat_version= file->s->key_stat_version-1; end: return (file ? 0 : 1); } int ha_heap::close(void) { return internal_table ? hp_close(file) : heap_close(file); } /* Create a copy of this table DESCRIPTION Do same as default implementation but use file->s->name instead of table->s->path. This is needed by Windows where the clone() call sees '/'-delimited path in table->s->path, while ha_heap::open() was called with '\'-delimited path. */ handler *ha_heap::clone(const char *name, MEM_ROOT *mem_root) { handler *new_handler= get_new_handler(table->s, mem_root, table->s->db_type()); if (new_handler && !new_handler->ha_open(table, file->s->name, table->db_stat, HA_OPEN_IGNORE_IF_LOCKED)) return new_handler; return NULL; /* purecov: inspected */ } /* Compute which keys to use for scanning SYNOPSIS set_keys_for_scanning() no parameter DESCRIPTION Set the bitmap btree_keys, which is used when the upper layers ask which keys to use for scanning. For each btree index the corresponding bit is set. RETURN void */ void ha_heap::set_keys_for_scanning(void) { btree_keys.clear_all(); for (uint i= 0 ; i < table->s->keys ; i++) { if (table->key_info[i].algorithm == HA_KEY_ALG_BTREE) btree_keys.set_bit(i); } } int ha_heap::can_continue_handler_scan() { int error= 0; if ((file->key_version != file->s->key_version && inited == INDEX) || (file->file_version != file->s->file_version && inited == RND)) { /* Data changed, not safe to do index or rnd scan */ error= HA_ERR_RECORD_CHANGED; } return error; } void ha_heap::update_key_stats() { for (uint i= 0; i < table->s->keys; i++) { KEY *key=table->key_info+i; if (!key->rec_per_key) continue; if (key->algorithm != HA_KEY_ALG_BTREE) { if (key->flags & HA_NOSAME) key->rec_per_key[key->user_defined_key_parts-1]= 1; else { ha_rows hash_buckets= file->s->keydef[i].hash_buckets; ha_rows no_records= hash_buckets ? (file->s->records/hash_buckets) : 2; if (no_records < 2) no_records= 2; key->rec_per_key[key->user_defined_key_parts-1]= no_records; } } } records_changed= 0; /* At the end of update_key_stats() we can proudly claim they are OK. */ key_stat_version= file->s->key_stat_version; } int ha_heap::write_row(uchar * buf) { int res; if (table->next_number_field && buf == table->record[0]) { if ((res= update_auto_increment())) return res; } res= heap_write(file,buf); if (!res && (++records_changed*HEAP_STATS_UPDATE_THRESHOLD > file->s->records)) { /* We can perform this safely since only one writer at the time is allowed on the table. */ records_changed= 0; file->s->key_stat_version++; } return res; } int ha_heap::update_row(const uchar * old_data, uchar * new_data) { int res; res= heap_update(file,old_data,new_data); if (!res && ++records_changed*HEAP_STATS_UPDATE_THRESHOLD > file->s->records) { /* We can perform this safely since only one writer at the time is allowed on the table. */ records_changed= 0; file->s->key_stat_version++; } return res; } int ha_heap::delete_row(const uchar * buf) { int res; res= heap_delete(file,buf); if (!res && table->s->tmp_table == NO_TMP_TABLE && ++records_changed*HEAP_STATS_UPDATE_THRESHOLD > file->s->records) { /* We can perform this safely since only one writer at the time is allowed on the table. */ records_changed= 0; file->s->key_stat_version++; } return res; } int ha_heap::index_read_map(uchar *buf, const uchar *key, key_part_map keypart_map, enum ha_rkey_function find_flag) { DBUG_ASSERT(inited==INDEX); int error = heap_rkey(file,buf,active_index, key, keypart_map, find_flag); return error; } int ha_heap::index_read_last_map(uchar *buf, const uchar *key, key_part_map keypart_map) { DBUG_ASSERT(inited==INDEX); int error= heap_rkey(file, buf, active_index, key, keypart_map, HA_READ_PREFIX_LAST); return error; } int ha_heap::index_read_idx_map(uchar *buf, uint index, const uchar *key, key_part_map keypart_map, enum ha_rkey_function find_flag) { int error = heap_rkey(file, buf, index, key, keypart_map, find_flag); return error; } int ha_heap::index_next(uchar * buf) { DBUG_ASSERT(inited==INDEX); int error=heap_rnext(file,buf); return error; } int ha_heap::index_prev(uchar * buf) { DBUG_ASSERT(inited==INDEX); int error=heap_rprev(file,buf); return error; } int ha_heap::index_first(uchar * buf) { DBUG_ASSERT(inited==INDEX); int error=heap_rfirst(file, buf, active_index); return error; } int ha_heap::index_last(uchar * buf) { DBUG_ASSERT(inited==INDEX); int error=heap_rlast(file, buf, active_index); return error; } int ha_heap::rnd_init(bool scan) { return scan ? heap_scan_init(file) : 0; } int ha_heap::rnd_next(uchar *buf) { int error=heap_scan(file, buf); return error; } int ha_heap::rnd_pos(uchar * buf, uchar *pos) { int error; HEAP_PTR heap_position; memcpy(&heap_position, pos, sizeof(HEAP_PTR)); error=heap_rrnd(file, buf, heap_position); return error; } void ha_heap::position(const uchar *record) { *(HEAP_PTR*) ref= heap_position(file); // Ref is aligned } int ha_heap::info(uint flag) { HEAPINFO hp_info; if (!table) return 1; (void) heap_info(file,&hp_info,flag); errkey= hp_info.errkey; stats.records= hp_info.records; stats.deleted= hp_info.deleted; stats.mean_rec_length= hp_info.reclength; stats.data_file_length= hp_info.data_length; stats.index_file_length= hp_info.index_length; stats.max_data_file_length= hp_info.max_records * hp_info.reclength; stats.delete_length= hp_info.deleted * hp_info.reclength; stats.create_time= (ulong) hp_info.create_time; if (flag & HA_STATUS_AUTO) stats.auto_increment_value= hp_info.auto_increment; /* If info() is called for the first time after open(), we will still have to update the key statistics. Hoping that a table lock is now in place. */ if (key_stat_version != file->s->key_stat_version) update_key_stats(); return 0; } int ha_heap::extra(enum ha_extra_function operation) { return heap_extra(file,operation); } int ha_heap::reset() { return heap_reset(file); } int ha_heap::delete_all_rows() { heap_clear(file); if (table->s->tmp_table == NO_TMP_TABLE) { /* We can perform this safely since only one writer at the time is allowed on the table. */ file->s->key_stat_version++; } return 0; } int ha_heap::reset_auto_increment(ulonglong value) { file->s->auto_increment= value; return 0; } int ha_heap::external_lock(THD *thd, int lock_type) { return 0; // No external locking } /* Disable indexes. SYNOPSIS disable_indexes() mode mode of operation: HA_KEY_SWITCH_NONUNIQ disable all non-unique keys HA_KEY_SWITCH_ALL disable all keys HA_KEY_SWITCH_NONUNIQ_SAVE dis. non-uni. and make persistent HA_KEY_SWITCH_ALL_SAVE dis. all keys and make persistent DESCRIPTION Disable indexes and clear keys to use for scanning. IMPLEMENTATION HA_KEY_SWITCH_NONUNIQ is not implemented. HA_KEY_SWITCH_NONUNIQ_SAVE is not implemented with HEAP. HA_KEY_SWITCH_ALL_SAVE is not implemented with HEAP. RETURN 0 ok HA_ERR_WRONG_COMMAND mode not implemented. */ int ha_heap::disable_indexes(uint mode) { int error; if (mode == HA_KEY_SWITCH_ALL) { if (!(error= heap_disable_indexes(file))) set_keys_for_scanning(); } else { /* mode not implemented */ error= HA_ERR_WRONG_COMMAND; } return error; } /* Enable indexes. SYNOPSIS enable_indexes() mode mode of operation: HA_KEY_SWITCH_NONUNIQ enable all non-unique keys HA_KEY_SWITCH_ALL enable all keys HA_KEY_SWITCH_NONUNIQ_SAVE en. non-uni. and make persistent HA_KEY_SWITCH_ALL_SAVE en. all keys and make persistent DESCRIPTION Enable indexes and set keys to use for scanning. The indexes might have been disabled by disable_index() before. The function works only if both data and indexes are empty, since the heap storage engine cannot repair the indexes. To be sure, call handler::delete_all_rows() before. IMPLEMENTATION HA_KEY_SWITCH_NONUNIQ is not implemented. HA_KEY_SWITCH_NONUNIQ_SAVE is not implemented with HEAP. HA_KEY_SWITCH_ALL_SAVE is not implemented with HEAP. RETURN 0 ok HA_ERR_CRASHED data or index is non-empty. Delete all rows and retry. HA_ERR_WRONG_COMMAND mode not implemented. */ int ha_heap::enable_indexes(uint mode) { int error; if (mode == HA_KEY_SWITCH_ALL) { if (!(error= heap_enable_indexes(file))) set_keys_for_scanning(); } else { /* mode not implemented */ error= HA_ERR_WRONG_COMMAND; } return error; } /* Test if indexes are disabled. SYNOPSIS indexes_are_disabled() no parameters RETURN 0 indexes are not disabled 1 all indexes are disabled [2 non-unique indexes are disabled - NOT YET IMPLEMENTED] */ int ha_heap::indexes_are_disabled(void) { return heap_indexes_are_disabled(file); } THR_LOCK_DATA **ha_heap::store_lock(THD *thd, THR_LOCK_DATA **to, enum thr_lock_type lock_type) { if (lock_type != TL_IGNORE && file->lock.type == TL_UNLOCK) file->lock.type=lock_type; *to++= &file->lock; return to; } /* We have to ignore ENOENT entries as the HEAP table is created on open and not when doing a CREATE on the table. */ int ha_heap::delete_table(const char *name) { int error= heap_delete_table(name); return error == ENOENT ? 0 : error; } void ha_heap::drop_table(const char *name) { file->s->delete_on_close= 1; ha_close(); } int ha_heap::rename_table(const char * from, const char * to) { return heap_rename(from,to); } ha_rows ha_heap::records_in_range(uint inx, key_range *min_key, key_range *max_key) { KEY *key=table->key_info+inx; if (key->algorithm == HA_KEY_ALG_BTREE) return hp_rb_records_in_range(file, inx, min_key, max_key); if (!min_key || !max_key || min_key->length != max_key->length || min_key->length != key->key_length || min_key->flag != HA_READ_KEY_EXACT || max_key->flag != HA_READ_AFTER_KEY) return HA_POS_ERROR; // Can only use exact keys if (stats.records <= 1) return stats.records; /* Assert that info() did run. We need current statistics here. */ DBUG_ASSERT(key_stat_version == file->s->key_stat_version); return key->rec_per_key[key->user_defined_key_parts-1]; } static int heap_prepare_hp_create_info(TABLE *table_arg, bool internal_table, HP_CREATE_INFO *hp_create_info) { uint key, parts, mem_per_row= 0, keys= table_arg->s->keys; uint auto_key= 0, auto_key_type= 0; ha_rows max_rows; HP_KEYDEF *keydef; HA_KEYSEG *seg; TABLE_SHARE *share= table_arg->s; bool found_real_auto_increment= 0; bzero(hp_create_info, sizeof(*hp_create_info)); for (key= parts= 0; key < keys; key++) parts+= table_arg->key_info[key].user_defined_key_parts; if (!(keydef= (HP_KEYDEF*) my_malloc(keys * sizeof(HP_KEYDEF) + parts * sizeof(HA_KEYSEG), MYF(MY_WME | MY_THREAD_SPECIFIC)))) return my_errno; seg= reinterpret_cast(keydef + keys); for (key= 0; key < keys; key++) { KEY *pos= table_arg->key_info+key; KEY_PART_INFO *key_part= pos->key_part; KEY_PART_INFO *key_part_end= key_part + pos->user_defined_key_parts; keydef[key].keysegs= (uint) pos->user_defined_key_parts; keydef[key].flag= (pos->flags & (HA_NOSAME | HA_NULL_ARE_EQUAL)); keydef[key].seg= seg; switch (pos->algorithm) { case HA_KEY_ALG_UNDEF: case HA_KEY_ALG_HASH: keydef[key].algorithm= HA_KEY_ALG_HASH; mem_per_row+= sizeof(char*) * 2; // = sizeof(HASH_INFO) break; case HA_KEY_ALG_BTREE: keydef[key].algorithm= HA_KEY_ALG_BTREE; mem_per_row+=sizeof(TREE_ELEMENT)+pos->key_length+sizeof(char*); break; default: DBUG_ASSERT(0); // cannot happen } for (; key_part != key_part_end; key_part++, seg++) { Field *field= key_part->field; if (pos->algorithm == HA_KEY_ALG_BTREE) seg->type= field->key_type(); else { if ((seg->type = field->key_type()) != (int) HA_KEYTYPE_TEXT && seg->type != HA_KEYTYPE_VARTEXT1 && seg->type != HA_KEYTYPE_VARTEXT2 && seg->type != HA_KEYTYPE_VARBINARY1 && seg->type != HA_KEYTYPE_VARBINARY2 && seg->type != HA_KEYTYPE_BIT) seg->type= HA_KEYTYPE_BINARY; } seg->start= (uint) key_part->offset; seg->length= (uint) key_part->length; seg->flag= key_part->key_part_flag; if (field->flags & (ENUM_FLAG | SET_FLAG)) seg->charset= &my_charset_bin; else seg->charset= field->charset_for_protocol(); if (field->null_ptr) { seg->null_bit= field->null_bit; seg->null_pos= (uint) (field->null_ptr - (uchar*) table_arg->record[0]); } else { seg->null_bit= 0; seg->null_pos= 0; } if (field->flags & AUTO_INCREMENT_FLAG && table_arg->found_next_number_field && key == share->next_number_index) { /* Store key number and type for found auto_increment key We have to store type as seg->type can differ from it */ auto_key= key+ 1; auto_key_type= field->key_type(); } if (seg->type == HA_KEYTYPE_BIT) { seg->bit_length= ((Field_bit *) field)->bit_len; seg->bit_start= ((Field_bit *) field)->bit_ofs; seg->bit_pos= (uint) (((Field_bit *) field)->bit_ptr - (uchar*) table_arg->record[0]); } else { seg->bit_length= seg->bit_start= 0; seg->bit_pos= 0; } } } mem_per_row+= MY_ALIGN(share->reclength + 1, sizeof(char*)); if (table_arg->found_next_number_field) { keydef[share->next_number_index].flag|= HA_AUTO_KEY; found_real_auto_increment= share->next_number_key_offset == 0; } hp_create_info->auto_key= auto_key; hp_create_info->auto_key_type= auto_key_type; hp_create_info->max_table_size=current_thd->variables.max_heap_table_size; hp_create_info->with_auto_increment= found_real_auto_increment; hp_create_info->internal_table= internal_table; max_rows= (ha_rows) (hp_create_info->max_table_size / mem_per_row); if (share->max_rows && share->max_rows < max_rows) max_rows= share->max_rows; hp_create_info->max_records= (ulong) MY_MIN(max_rows, ULONG_MAX); hp_create_info->min_records= (ulong) MY_MIN(share->min_rows, ULONG_MAX); hp_create_info->keys= share->keys; hp_create_info->reclength= share->reclength; hp_create_info->keydef= keydef; return 0; } int ha_heap::create(const char *name, TABLE *table_arg, HA_CREATE_INFO *create_info) { int error; my_bool created; HP_CREATE_INFO hp_create_info; error= heap_prepare_hp_create_info(table_arg, internal_table, &hp_create_info); if (error) return error; hp_create_info.auto_increment= (create_info->auto_increment_value ? create_info->auto_increment_value - 1 : 0); error= heap_create(name, &hp_create_info, &internal_share, &created); my_free(hp_create_info.keydef); DBUG_ASSERT(file == 0); return (error); } void ha_heap::update_create_info(HA_CREATE_INFO *create_info) { table->file->info(HA_STATUS_AUTO); if (!(create_info->used_fields & HA_CREATE_USED_AUTO)) create_info->auto_increment_value= stats.auto_increment_value; } void ha_heap::get_auto_increment(ulonglong offset, ulonglong increment, ulonglong nb_desired_values, ulonglong *first_value, ulonglong *nb_reserved_values) { ha_heap::info(HA_STATUS_AUTO); *first_value= stats.auto_increment_value; /* such table has only table-level locking so reserves up to +inf */ *nb_reserved_values= ULONGLONG_MAX; } bool ha_heap::check_if_incompatible_data(HA_CREATE_INFO *info, uint table_changes) { /* Check that auto_increment value was not changed */ if ((info->used_fields & HA_CREATE_USED_AUTO && info->auto_increment_value != 0) || table_changes == IS_EQUAL_NO || table_changes & IS_EQUAL_PACK_LENGTH) // Not implemented yet return COMPATIBLE_DATA_NO; return COMPATIBLE_DATA_YES; } struct st_mysql_storage_engine heap_storage_engine= { MYSQL_HANDLERTON_INTERFACE_VERSION }; mysql_declare_plugin(heap) { MYSQL_STORAGE_ENGINE_PLUGIN, &heap_storage_engine, "MEMORY", "MySQL AB", "Hash based, stored in memory, useful for temporary tables", PLUGIN_LICENSE_GPL, heap_init, NULL, 0x0100, /* 1.0 */ NULL, /* status variables */ NULL, /* system variables */ NULL, /* config options */ 0, /* flags */ } mysql_declare_plugin_end; maria_declare_plugin(heap) { MYSQL_STORAGE_ENGINE_PLUGIN, &heap_storage_engine, "MEMORY", "MySQL AB", "Hash based, stored in memory, useful for temporary tables", PLUGIN_LICENSE_GPL, heap_init, NULL, 0x0100, /* 1.0 */ NULL, /* status variables */ NULL, /* system variables */ "1.0", /* string version */ MariaDB_PLUGIN_MATURITY_STABLE /* maturity */ } maria_declare_plugin_end;