/* Copyright (c) 2013 Monty Program Ab 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 02110-1335 USA */ /* a engine that auto-creates tables with rows filled with sequential values */ #include #include #include #include #include #include #include #include #include static handlerton *sequence_hton; class Sequence_share : public Handler_share { public: const char *name; THR_LOCK lock; ulonglong from, to, step; bool reverse; Sequence_share(const char *name_arg, ulonglong from_arg, ulonglong to_arg, ulonglong step_arg, bool reverse_arg): name(name_arg), from(from_arg), to(to_arg), step(step_arg), reverse(reverse_arg) { thr_lock_init(&lock); } ~Sequence_share() { thr_lock_delete(&lock); } }; class ha_seq final : public handler { private: THR_LOCK_DATA lock; Sequence_share *get_share(); ulonglong cur; public: Sequence_share *seqs; ha_seq(handlerton *hton, TABLE_SHARE *table_arg) : handler(hton, table_arg), seqs(0) { } ulonglong table_flags() const { return HA_BINLOG_ROW_CAPABLE | HA_BINLOG_STMT_CAPABLE; } /* open/close/locking */ int create(const char *name, TABLE *table_arg, HA_CREATE_INFO *create_info) { return HA_ERR_WRONG_COMMAND; } int open(const char *name, int mode, uint test_if_locked); int close(void); int delete_table(const char *name) { return 0; } THR_LOCK_DATA **store_lock(THD *, THR_LOCK_DATA **, enum thr_lock_type); /* table scan */ int rnd_init(bool scan); int rnd_next(unsigned char *buf); void position(const uchar *record); int rnd_pos(uchar *buf, uchar *pos); int info(uint flag); /* indexes */ ulong index_flags(uint inx, uint part, bool all_parts) const { return HA_READ_NEXT | HA_READ_PREV | HA_READ_ORDER | HA_READ_RANGE | HA_KEYREAD_ONLY; } uint max_supported_keys() const { return 1; } int index_read_map(uchar *buf, const uchar *key, key_part_map keypart_map, enum ha_rkey_function find_flag); int index_next(uchar *buf); int index_prev(uchar *buf); int index_first(uchar *buf); int index_last(uchar *buf); ha_rows records_in_range(uint inx, const key_range *start_key, const key_range *end_key, page_range *pages); double scan_time() { return (double)nvalues(); } double read_time(uint index, uint ranges, ha_rows rows) { return (double)rows; } double keyread_time(uint index, uint ranges, ha_rows rows) { return (double)rows; } private: void set(uchar *buf); ulonglong nvalues() { return (seqs->to - seqs->from)/seqs->step; } }; THR_LOCK_DATA **ha_seq::store_lock(THD *thd, THR_LOCK_DATA **to, enum thr_lock_type lock_type) { if (lock_type != TL_IGNORE && lock.type == TL_UNLOCK) lock.type= TL_WRITE_ALLOW_WRITE; *to ++= &lock; return to; } void ha_seq::set(unsigned char *buf) { MY_BITMAP *old_map = dbug_tmp_use_all_columns(table, &table->write_set); my_ptrdiff_t offset = (my_ptrdiff_t) (buf - table->record[0]); Field *field = table->field[0]; field->move_field_offset(offset); field->store(cur, true); field->move_field_offset(-offset); dbug_tmp_restore_column_map(&table->write_set, old_map); } int ha_seq::rnd_init(bool scan) { cur= seqs->reverse ? seqs->to : seqs->from; return 0; } int ha_seq::rnd_next(unsigned char *buf) { if (seqs->reverse) return index_prev(buf); else return index_next(buf); } void ha_seq::position(const uchar *record) { *(ulonglong*)ref= cur; } int ha_seq::rnd_pos(uchar *buf, uchar *pos) { cur= *(ulonglong*)pos; return rnd_next(buf); } int ha_seq::info(uint flag) { if (flag & HA_STATUS_VARIABLE) stats.records = nvalues(); return 0; } int ha_seq::index_read_map(uchar *buf, const uchar *key_arg, key_part_map keypart_map, enum ha_rkey_function find_flag) { ulonglong key= uint8korr(key_arg); switch (find_flag) { case HA_READ_AFTER_KEY: key++; // fall through case HA_READ_KEY_OR_NEXT: if (key <= seqs->from) cur= seqs->from; else { cur= (key - seqs->from + seqs->step - 1) / seqs->step * seqs->step + seqs->from; if (cur >= seqs->to) return HA_ERR_KEY_NOT_FOUND; } return index_next(buf); case HA_READ_KEY_EXACT: if ((key - seqs->from) % seqs->step != 0 || key < seqs->from || key >= seqs->to) return HA_ERR_KEY_NOT_FOUND; cur= key; return index_next(buf); case HA_READ_BEFORE_KEY: key--; // fall through case HA_READ_PREFIX_LAST_OR_PREV: if (key >= seqs->to) cur= seqs->to; else { if (key < seqs->from) return HA_ERR_KEY_NOT_FOUND; cur= (key - seqs->from) / seqs->step * seqs->step + seqs->from; } return index_prev(buf); default: return HA_ERR_WRONG_COMMAND; } } int ha_seq::index_next(uchar *buf) { if (cur == seqs->to) return HA_ERR_END_OF_FILE; set(buf); cur+= seqs->step; return 0; } int ha_seq::index_prev(uchar *buf) { if (cur == seqs->from) return HA_ERR_END_OF_FILE; cur-= seqs->step; set(buf); return 0; } int ha_seq::index_first(uchar *buf) { cur= seqs->from; return index_next(buf); } int ha_seq::index_last(uchar *buf) { cur= seqs->to; return index_prev(buf); } ha_rows ha_seq::records_in_range(uint inx, const key_range *min_key, const key_range *max_key, page_range *pages) { ulonglong kmin= min_key ? uint8korr(min_key->key) : seqs->from; ulonglong kmax= max_key ? uint8korr(max_key->key) : seqs->to - 1; if (kmin >= seqs->to || kmax < seqs->from || kmin > kmax) return 0; return (kmax - seqs->from) / seqs->step - (kmin - seqs->from + seqs->step - 1) / seqs->step + 1; } int ha_seq::open(const char *name, int mode, uint test_if_locked) { if (!(seqs= get_share())) return HA_ERR_OUT_OF_MEM; DBUG_ASSERT(my_strcasecmp(table_alias_charset, name, seqs->name) == 0); ref_length= sizeof(cur); thr_lock_data_init(&seqs->lock,&lock,NULL); return 0; } int ha_seq::close(void) { return 0; } static handler *create_handler(handlerton *hton, TABLE_SHARE *table, MEM_ROOT *mem_root) { return new (mem_root) ha_seq(hton, table); } static bool parse_table_name(const char *name, size_t name_length, ulonglong *from, ulonglong *to, ulonglong *step) { uint n0=0, n1= 0, n2= 0; *step= 1; // the table is discovered if its name matches the pattern of seq_1_to_10 or // seq_1_to_10_step_3 sscanf(name, "seq_%llu_to_%n%llu%n_step_%llu%n", from, &n0, to, &n1, step, &n2); // I consider this a bug in sscanf() - when an unsigned number // is requested, -5 should *not* be accepted. But is is :( // hence the additional check below: return n0 == 0 || !isdigit(name[4]) || !isdigit(name[n0]) || // reject negative numbers (n1 != name_length && n2 != name_length); } Sequence_share *ha_seq::get_share() { Sequence_share *tmp_share; lock_shared_ha_data(); if (!(tmp_share= static_cast(get_ha_share_ptr()))) { bool reverse; ulonglong from, to, step; parse_table_name(table_share->table_name.str, table_share->table_name.length, &from, &to, &step); if ((reverse = from > to)) { if (step > from - to) to = from; else swap_variables(ulonglong, from, to); /* when keyread is allowed, optimizer will always prefer an index to a table scan for our tables, and we'll never see the range reversed. */ table_share->keys_for_keyread.clear_all(); } to= (to - from) / step * step + step + from; tmp_share= new Sequence_share(table_share->normalized_path.str, from, to, step, reverse); if (!tmp_share) goto err; set_ha_share_ptr(static_cast(tmp_share)); } err: unlock_shared_ha_data(); return tmp_share; } static int discover_table(handlerton *hton, THD *thd, TABLE_SHARE *share) { ulonglong from, to, step; if (parse_table_name(share->table_name.str, share->table_name.length, &from, &to, &step)) return HA_ERR_NO_SUCH_TABLE; if (step == 0) return HA_WRONG_CREATE_OPTION; const char *sql="create table seq (seq bigint unsigned primary key)"; return share->init_from_sql_statement_string(thd, 0, sql, strlen(sql)); } static int discover_table_existence(handlerton *hton, const char *db, const char *table_name) { ulonglong from, to, step; return !parse_table_name(table_name, strlen(table_name), &from, &to, &step); } static int dummy_commit_rollback(handlerton *, THD *, bool) { return 0; } static int dummy_savepoint(handlerton *, THD *, void *) { return 0; } /***************************************************************************** Example of a simple group by handler for queries like: SELECT SUM(seq) from sequence_table; This implementation supports SUM() and COUNT() on primary key. *****************************************************************************/ class ha_seq_group_by_handler: public group_by_handler { Select_limit_counters limit; List *fields; TABLE_LIST *table_list; bool first_row; public: ha_seq_group_by_handler(THD *thd_arg, List *fields_arg, TABLE_LIST *table_list_arg, Select_limit_counters *orig_lim) : group_by_handler(thd_arg, sequence_hton), limit(orig_lim[0]), fields(fields_arg), table_list(table_list_arg) { // Reset limit because we are handling it now orig_lim->set_unlimited(); } ~ha_seq_group_by_handler() = default; int init_scan() { first_row= 1 ; return 0; } int next_row(); int end_scan() { return 0; } }; static group_by_handler * create_group_by_handler(THD *thd, Query *query) { ha_seq_group_by_handler *handler; Item *item; List_iterator_fast it(*query->select); /* check that only one table is used in FROM clause and no sub queries */ if (query->from->next_local != 0) return 0; /* check that there is no where clause and no group_by */ if (query->where != 0 || query->group_by != 0) return 0; /* Check that all fields are sum(primary_key) or count(primary_key) For more ways to work with the field list and sum functions, see opt_sum.cc::opt_sum_query(). */ while ((item= it++)) { Item *arg0; Field *field; if (item->type() != Item::SUM_FUNC_ITEM || (((Item_sum*) item)->sum_func() != Item_sum::SUM_FUNC && ((Item_sum*) item)->sum_func() != Item_sum::COUNT_FUNC)) return 0; // Not a SUM() function arg0= ((Item_sum*) item)->get_arg(0); if (arg0->type() != Item::FIELD_ITEM) { if ((((Item_sum*) item)->sum_func() == Item_sum::COUNT_FUNC) && arg0->basic_const_item()) continue; // Allow count(1) return 0; } field= ((Item_field*) arg0)->field; /* Check that we are using the sequence table (the only table in the FROM clause) and not an outer table. */ if (field->table != query->from->table) return 0; /* Check that we are using a SUM() on the primary key */ if (strcmp(field->field_name.str, "seq")) return 0; } /* Create handler and return it */ handler= new ha_seq_group_by_handler(thd, query->select, query->from, query->limit); return handler; } int ha_seq_group_by_handler::next_row() { List_iterator_fast it(*fields); Item_sum *item_sum; Sequence_share *seqs= ((ha_seq*) table_list->table->file)->seqs; DBUG_ENTER("ha_seq_group_by_handler::next_row"); /* Check if this is the first call to the function. If not, we have already returned all data. */ if (!first_row || limit.get_offset_limit() > 0 || limit.get_select_limit() == 0) DBUG_RETURN(HA_ERR_END_OF_FILE); first_row= 0; /* Pointer to first field in temporary table where we should store summary*/ Field **field_ptr= table->field; ulonglong elements= (seqs->to - seqs->from + seqs->step - 1) / seqs->step; while ((item_sum= (Item_sum*) it++)) { Field *field= *(field_ptr++); switch (item_sum->sum_func()) { case Item_sum::COUNT_FUNC: { Item *arg0= ((Item_sum*) item_sum)->get_arg(0); if (arg0->basic_const_item() && arg0->is_null()) field->store(0LL, 1); else field->store((longlong) elements, 1); break; } case Item_sum::SUM_FUNC: { /* Calculate SUM(f, f+step, f+step*2 ... to) */ ulonglong sum; sum= seqs->from * elements + seqs->step * (elements*elements-elements)/2; field->store((longlong) sum, 1); break; } default: DBUG_ASSERT(0); } field->set_notnull(); } DBUG_RETURN(0); } /***************************************************************************** Initialize the interface between the sequence engine and MariaDB *****************************************************************************/ static int drop_table(handlerton *hton, const char *path) { const char *name= strrchr(path, FN_LIBCHAR)+1; ulonglong from, to, step; if (parse_table_name(name, strlen(name), &from, &to, &step)) return ENOENT; return 0; } static int init(void *p) { handlerton *hton= (handlerton *)p; sequence_hton= hton; hton->create= create_handler; hton->drop_table= drop_table; hton->discover_table= discover_table; hton->discover_table_existence= discover_table_existence; hton->commit= hton->rollback= dummy_commit_rollback; hton->savepoint_set= hton->savepoint_rollback= hton->savepoint_release= dummy_savepoint; hton->create_group_by= create_group_by_handler; return 0; } static struct st_mysql_storage_engine descriptor = { MYSQL_HANDLERTON_INTERFACE_VERSION }; maria_declare_plugin(sequence) { MYSQL_STORAGE_ENGINE_PLUGIN, &descriptor, "SEQUENCE", "Sergei Golubchik", "Generated tables filled with sequential values", PLUGIN_LICENSE_GPL, init, NULL, 0x0100, NULL, NULL, "0.1", MariaDB_PLUGIN_MATURITY_STABLE } maria_declare_plugin_end;