/***************************************************************************** Copyright (c) 1996, 2014, Oracle and/or its affiliates. All Rights Reserved. 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 Street, Suite 500, Boston, MA 02110-1335 USA *****************************************************************************/ /**************************************************//** @file trx/trx0roll.cc Transaction rollback Created 3/26/1996 Heikki Tuuri *******************************************************/ #include "trx0roll.h" #ifdef UNIV_NONINL #include "trx0roll.ic" #endif #include #include "fsp0fsp.h" #include "mach0data.h" #include "trx0rseg.h" #include "trx0trx.h" #include "trx0undo.h" #include "trx0rec.h" #include "que0que.h" #include "usr0sess.h" #include "srv0start.h" #include "read0read.h" #include "row0undo.h" #include "row0mysql.h" #include "lock0lock.h" #include "pars0pars.h" #include "srv0mon.h" #include "trx0sys.h" #ifdef WITH_WSREP #include "ha_prototypes.h" #endif /* WITH_WSREP */ /** This many pages must be undone before a truncate is tried within rollback */ #define TRX_ROLL_TRUNC_THRESHOLD 1 /** In crash recovery, the current trx to be rolled back; NULL otherwise */ static const trx_t* trx_roll_crash_recv_trx = NULL; /** In crash recovery we set this to the undo n:o of the current trx to be rolled back. Then we can print how many % the rollback has progressed. */ static undo_no_t trx_roll_max_undo_no; /** Auxiliary variable which tells the previous progress % we printed */ static ulint trx_roll_progress_printed_pct; /****************************************************************//** Finishes a transaction rollback. */ static void trx_rollback_finish( /*================*/ trx_t* trx); /*!< in: transaction */ /*******************************************************************//** Rollback a transaction used in MySQL. */ static void trx_rollback_to_savepoint_low( /*==========================*/ trx_t* trx, /*!< in: transaction handle */ trx_savept_t* savept) /*!< in: pointer to savepoint undo number, if partial rollback requested, or NULL for complete rollback */ { que_thr_t* thr; mem_heap_t* heap; roll_node_t* roll_node; heap = mem_heap_create(512); roll_node = roll_node_create(heap); if (savept != NULL) { roll_node->partial = TRUE; roll_node->savept = *savept; assert_trx_in_list(trx); } else { assert_trx_nonlocking_or_in_list(trx); } trx->error_state = DB_SUCCESS; if (trx->insert_undo || trx->update_undo) { thr = pars_complete_graph_for_exec(roll_node, trx, heap); ut_a(thr == que_fork_start_command( static_cast(que_node_get_parent(thr)))); que_run_threads(thr); ut_a(roll_node->undo_thr != NULL); que_run_threads(roll_node->undo_thr); /* Free the memory reserved by the undo graph. */ que_graph_free(static_cast( roll_node->undo_thr->common.parent)); } if (savept == NULL) { trx_rollback_finish(trx); MONITOR_INC(MONITOR_TRX_ROLLBACK); } else { trx->lock.que_state = TRX_QUE_RUNNING; MONITOR_INC(MONITOR_TRX_ROLLBACK_SAVEPOINT); } ut_a(trx->error_state == DB_SUCCESS); ut_a(trx->lock.que_state == TRX_QUE_RUNNING); mem_heap_free(heap); /* There might be work for utility threads.*/ srv_active_wake_master_thread(); MONITOR_DEC(MONITOR_TRX_ACTIVE); } /*******************************************************************//** Rollback a transaction to a given savepoint or do a complete rollback. @return error code or DB_SUCCESS */ UNIV_INTERN dberr_t trx_rollback_to_savepoint( /*======================*/ trx_t* trx, /*!< in: transaction handle */ trx_savept_t* savept) /*!< in: pointer to savepoint undo number, if partial rollback requested, or NULL for complete rollback */ { ut_ad(!trx_mutex_own(trx)); trx_start_if_not_started_xa(trx); trx_rollback_to_savepoint_low(trx, savept); return(trx->error_state); } /*******************************************************************//** Rollback a transaction used in MySQL. @return error code or DB_SUCCESS */ static dberr_t trx_rollback_for_mysql_low( /*=======================*/ trx_t* trx) /*!< in/out: transaction */ { trx->op_info = "rollback"; /* If we are doing the XA recovery of prepared transactions, then the transaction object does not have an InnoDB session object, and we set a dummy session that we use for all MySQL transactions. */ trx_rollback_to_savepoint_low(trx, NULL); trx->op_info = ""; ut_a(trx->error_state == DB_SUCCESS); return(trx->error_state); } /*******************************************************************//** Rollback a transaction used in MySQL. @return error code or DB_SUCCESS */ UNIV_INTERN dberr_t trx_rollback_for_mysql( /*===================*/ trx_t* trx) /*!< in/out: transaction */ { /* We are reading trx->state without holding trx_sys->mutex here, because the rollback should be invoked for a running active MySQL transaction (or recovered prepared transaction) that is associated with the current thread. */ switch (trx->state) { case TRX_STATE_NOT_STARTED: ut_ad(trx->in_mysql_trx_list); return(DB_SUCCESS); case TRX_STATE_ACTIVE: ut_ad(trx->in_mysql_trx_list); assert_trx_nonlocking_or_in_list(trx); return(trx_rollback_for_mysql_low(trx)); case TRX_STATE_PREPARED: ut_ad(!trx_is_autocommit_non_locking(trx)); return(trx_rollback_for_mysql_low(trx)); case TRX_STATE_COMMITTED_IN_MEMORY: assert_trx_in_list(trx); break; } ut_error; return(DB_CORRUPTION); } /*******************************************************************//** Rollback the latest SQL statement for MySQL. @return error code or DB_SUCCESS */ UNIV_INTERN dberr_t trx_rollback_last_sql_stat_for_mysql( /*=================================*/ trx_t* trx) /*!< in/out: transaction */ { dberr_t err; /* We are reading trx->state without holding trx_sys->mutex here, because the statement rollback should be invoked for a running active MySQL transaction that is associated with the current thread. */ ut_ad(trx->in_mysql_trx_list); switch (trx->state) { case TRX_STATE_NOT_STARTED: return(DB_SUCCESS); case TRX_STATE_ACTIVE: assert_trx_nonlocking_or_in_list(trx); trx->op_info = "rollback of SQL statement"; err = trx_rollback_to_savepoint( trx, &trx->last_sql_stat_start); if (trx->fts_trx) { fts_savepoint_rollback_last_stmt(trx); } /* The following call should not be needed, but we play it safe: */ trx_mark_sql_stat_end(trx); trx->op_info = ""; return(err); case TRX_STATE_PREPARED: case TRX_STATE_COMMITTED_IN_MEMORY: /* The statement rollback is only allowed on an ACTIVE transaction, not a PREPARED or COMMITTED one. */ break; } ut_error; return(DB_CORRUPTION); } /*******************************************************************//** Search for a savepoint using name. @return savepoint if found else NULL */ static trx_named_savept_t* trx_savepoint_find( /*===============*/ trx_t* trx, /*!< in: transaction */ const char* name) /*!< in: savepoint name */ { trx_named_savept_t* savep; for (savep = UT_LIST_GET_FIRST(trx->trx_savepoints); savep != NULL; savep = UT_LIST_GET_NEXT(trx_savepoints, savep)) { if (0 == ut_strcmp(savep->name, name)) { return(savep); } } return(NULL); } /*******************************************************************//** Frees a single savepoint struct. */ static void trx_roll_savepoint_free( /*=====================*/ trx_t* trx, /*!< in: transaction handle */ trx_named_savept_t* savep) /*!< in: savepoint to free */ { UT_LIST_REMOVE(trx_savepoints, trx->trx_savepoints, savep); mem_free(savep->name); mem_free(savep); } /*******************************************************************//** Frees savepoint structs starting from savep. */ UNIV_INTERN void trx_roll_savepoints_free( /*=====================*/ trx_t* trx, /*!< in: transaction handle */ trx_named_savept_t* savep) /*!< in: free all savepoints starting with this savepoint i*/ { while (savep != NULL) { trx_named_savept_t* next_savep; next_savep = UT_LIST_GET_NEXT(trx_savepoints, savep); trx_roll_savepoint_free(trx, savep); savep = next_savep; } } /*******************************************************************//** Rolls back a transaction back to a named savepoint. Modifications after the savepoint are undone but InnoDB does NOT release the corresponding locks which are stored in memory. If a lock is 'implicit', that is, a new inserted row holds a lock where the lock information is carried by the trx id stored in the row, these locks are naturally released in the rollback. Savepoints which were set after this savepoint are deleted. @return if no savepoint of the name found then DB_NO_SAVEPOINT, otherwise DB_SUCCESS */ static __attribute__((nonnull, warn_unused_result)) dberr_t trx_rollback_to_savepoint_for_mysql_low( /*====================================*/ trx_t* trx, /*!< in/out: transaction */ trx_named_savept_t* savep, /*!< in/out: savepoint */ ib_int64_t* mysql_binlog_cache_pos) /*!< out: the MySQL binlog cache position corresponding to this savepoint; MySQL needs this information to remove the binlog entries of the queries executed after the savepoint */ { dberr_t err; ut_ad(trx_state_eq(trx, TRX_STATE_ACTIVE)); ut_ad(trx->in_mysql_trx_list); /* Free all savepoints strictly later than savep. */ trx_roll_savepoints_free( trx, UT_LIST_GET_NEXT(trx_savepoints, savep)); *mysql_binlog_cache_pos = savep->mysql_binlog_cache_pos; trx->op_info = "rollback to a savepoint"; err = trx_rollback_to_savepoint(trx, &savep->savept); /* Store the current undo_no of the transaction so that we know where to roll back if we have to roll back the next SQL statement: */ trx_mark_sql_stat_end(trx); trx->op_info = ""; #ifdef WITH_WSREP if (wsrep_on(trx->mysql_thd) && trx->lock.was_chosen_as_deadlock_victim) { trx->lock.was_chosen_as_deadlock_victim = FALSE; } #endif return(err); } /*******************************************************************//** Rolls back a transaction back to a named savepoint. Modifications after the savepoint are undone but InnoDB does NOT release the corresponding locks which are stored in memory. If a lock is 'implicit', that is, a new inserted row holds a lock where the lock information is carried by the trx id stored in the row, these locks are naturally released in the rollback. Savepoints which were set after this savepoint are deleted. @return if no savepoint of the name found then DB_NO_SAVEPOINT, otherwise DB_SUCCESS */ UNIV_INTERN dberr_t trx_rollback_to_savepoint_for_mysql( /*================================*/ trx_t* trx, /*!< in: transaction handle */ const char* savepoint_name, /*!< in: savepoint name */ ib_int64_t* mysql_binlog_cache_pos) /*!< out: the MySQL binlog cache position corresponding to this savepoint; MySQL needs this information to remove the binlog entries of the queries executed after the savepoint */ { trx_named_savept_t* savep; /* We are reading trx->state without holding trx_sys->mutex here, because the savepoint rollback should be invoked for a running active MySQL transaction that is associated with the current thread. */ ut_ad(trx->in_mysql_trx_list); savep = trx_savepoint_find(trx, savepoint_name); if (savep == NULL) { return(DB_NO_SAVEPOINT); } switch (trx->state) { case TRX_STATE_NOT_STARTED: ut_print_timestamp(stderr); fputs(" InnoDB: Error: transaction has a savepoint ", stderr); ut_print_name(stderr, trx, FALSE, savep->name); fputs(" though it is not started\n", stderr); return(DB_ERROR); case TRX_STATE_ACTIVE: return(trx_rollback_to_savepoint_for_mysql_low( trx, savep, mysql_binlog_cache_pos)); case TRX_STATE_PREPARED: case TRX_STATE_COMMITTED_IN_MEMORY: /* The savepoint rollback is only allowed on an ACTIVE transaction, not a PREPARED or COMMITTED one. */ break; } ut_error; return(DB_CORRUPTION); } /*******************************************************************//** Creates a named savepoint. If the transaction is not yet started, starts it. If there is already a savepoint of the same name, this call erases that old savepoint and replaces it with a new. Savepoints are deleted in a transaction commit or rollback. @return always DB_SUCCESS */ UNIV_INTERN dberr_t trx_savepoint_for_mysql( /*====================*/ trx_t* trx, /*!< in: transaction handle */ const char* savepoint_name, /*!< in: savepoint name */ ib_int64_t binlog_cache_pos) /*!< in: MySQL binlog cache position corresponding to this connection at the time of the savepoint */ { trx_named_savept_t* savep; trx_start_if_not_started_xa(trx); savep = trx_savepoint_find(trx, savepoint_name); if (savep) { /* There is a savepoint with the same name: free that */ UT_LIST_REMOVE(trx_savepoints, trx->trx_savepoints, savep); mem_free(savep->name); mem_free(savep); } /* Create a new savepoint and add it as the last in the list */ savep = static_cast(mem_alloc(sizeof(*savep))); savep->name = mem_strdup(savepoint_name); savep->savept = trx_savept_take(trx); savep->mysql_binlog_cache_pos = binlog_cache_pos; UT_LIST_ADD_LAST(trx_savepoints, trx->trx_savepoints, savep); return(DB_SUCCESS); } /*******************************************************************//** Releases only the named savepoint. Savepoints which were set after this savepoint are left as is. @return if no savepoint of the name found then DB_NO_SAVEPOINT, otherwise DB_SUCCESS */ UNIV_INTERN dberr_t trx_release_savepoint_for_mysql( /*============================*/ trx_t* trx, /*!< in: transaction handle */ const char* savepoint_name) /*!< in: savepoint name */ { trx_named_savept_t* savep; ut_ad(trx_state_eq(trx, TRX_STATE_ACTIVE)); ut_ad(trx->in_mysql_trx_list); savep = trx_savepoint_find(trx, savepoint_name); if (savep != NULL) { trx_roll_savepoint_free(trx, savep); } return(savep != NULL ? DB_SUCCESS : DB_NO_SAVEPOINT); } /*******************************************************************//** Determines if this transaction is rolling back an incomplete transaction in crash recovery. @return TRUE if trx is an incomplete transaction that is being rolled back in crash recovery */ UNIV_INTERN ibool trx_is_recv( /*========*/ const trx_t* trx) /*!< in: transaction */ { return(trx == trx_roll_crash_recv_trx); } /*******************************************************************//** Returns a transaction savepoint taken at this point in time. @return savepoint */ UNIV_INTERN trx_savept_t trx_savept_take( /*============*/ trx_t* trx) /*!< in: transaction */ { trx_savept_t savept; savept.least_undo_no = trx->undo_no; return(savept); } /*******************************************************************//** Roll back an active transaction. */ static void trx_rollback_active( /*================*/ trx_t* trx) /*!< in/out: transaction */ { mem_heap_t* heap; que_fork_t* fork; que_thr_t* thr; roll_node_t* roll_node; dict_table_t* table; ib_int64_t rows_to_undo; const char* unit = ""; ibool dictionary_locked = FALSE; heap = mem_heap_create(512); fork = que_fork_create(NULL, NULL, QUE_FORK_RECOVERY, heap); fork->trx = trx; thr = que_thr_create(fork, heap); roll_node = roll_node_create(heap); thr->child = roll_node; roll_node->common.parent = thr; trx->graph = fork; ut_a(thr == que_fork_start_command(fork)); mutex_enter(&trx_sys->mutex); trx_roll_crash_recv_trx = trx; trx_roll_max_undo_no = trx->undo_no; trx_roll_progress_printed_pct = 0; rows_to_undo = trx_roll_max_undo_no; mutex_exit(&trx_sys->mutex); if (rows_to_undo > 1000000000) { rows_to_undo = rows_to_undo / 1000000; unit = "M"; } ut_print_timestamp(stderr); fprintf(stderr, " InnoDB: Rolling back trx with id " TRX_ID_FMT ", %lu%s" " rows to undo\n", trx->id, (ulong) rows_to_undo, unit); if (trx_get_dict_operation(trx) != TRX_DICT_OP_NONE) { row_mysql_lock_data_dictionary(trx); dictionary_locked = TRUE; } que_run_threads(thr); ut_a(roll_node->undo_thr != NULL); que_run_threads(roll_node->undo_thr); trx_rollback_finish(thr_get_trx(roll_node->undo_thr)); /* Free the memory reserved by the undo graph */ que_graph_free(static_cast( roll_node->undo_thr->common.parent)); ut_a(trx->lock.que_state == TRX_QUE_RUNNING); if (trx_get_dict_operation(trx) != TRX_DICT_OP_NONE && trx->table_id != 0) { /* If the transaction was for a dictionary operation, we drop the relevant table only if it is not flagged as DISCARDED. If it still exists. */ table = dict_table_open_on_id( trx->table_id, dictionary_locked, DICT_TABLE_OP_NORMAL); if (table && !dict_table_is_discarded(table)) { dberr_t err; /* Ensure that the table doesn't get evicted from the cache, keeps things simple for drop. */ if (table->can_be_evicted) { dict_table_move_from_lru_to_non_lru(table); } dict_table_close(table, dictionary_locked, FALSE); ib_logf(IB_LOG_LEVEL_WARN, "Dropping table '%s', with id " UINT64PF " " "in recovery", table->name, trx->table_id); err = row_drop_table_for_mysql(table->name, trx, TRUE); trx_commit_for_mysql(trx); ut_a(err == DB_SUCCESS); } } if (dictionary_locked) { row_mysql_unlock_data_dictionary(trx); } ib_logf(IB_LOG_LEVEL_INFO, "Rollback of trx with id " TRX_ID_FMT " completed", trx->id); mem_heap_free(heap); trx_roll_crash_recv_trx = NULL; } /*******************************************************************//** Rollback or clean up any resurrected incomplete transactions. It assumes that the caller holds the trx_sys_t::mutex and it will release the lock if it does a clean up or rollback. @return TRUE if the transaction was cleaned up or rolled back and trx_sys->mutex was released. */ static ibool trx_rollback_resurrected( /*=====================*/ trx_t* trx, /*!< in: transaction to rollback or clean */ ibool all) /*!< in: FALSE=roll back dictionary transactions; TRUE=roll back all non-PREPARED transactions */ { ut_ad(mutex_own(&trx_sys->mutex)); /* The trx->is_recovered flag and trx->state are set atomically under the protection of the trx->mutex (and lock_sys->mutex) in lock_trx_release_locks(). We do not want to accidentally clean up a non-recovered transaction here. */ trx_mutex_enter(trx); bool is_recovered = trx->is_recovered; trx_state_t state = trx->state; trx_mutex_exit(trx); if (!is_recovered) { return(FALSE); } switch (state) { case TRX_STATE_COMMITTED_IN_MEMORY: mutex_exit(&trx_sys->mutex); fprintf(stderr, "InnoDB: Cleaning up trx with id " TRX_ID_FMT "\n", trx->id); trx_cleanup_at_db_startup(trx); trx_free_for_background(trx); return(TRUE); case TRX_STATE_ACTIVE: if (all || trx_get_dict_operation(trx) != TRX_DICT_OP_NONE) { mutex_exit(&trx_sys->mutex); trx_rollback_active(trx); trx_free_for_background(trx); return(TRUE); } return(FALSE); case TRX_STATE_PREPARED: return(FALSE); case TRX_STATE_NOT_STARTED: break; } ut_error; return(FALSE); } /*******************************************************************//** Rollback or clean up any incomplete transactions which were encountered in crash recovery. If the transaction already was committed, then we clean up a possible insert undo log. If the transaction was not yet committed, then we roll it back. */ UNIV_INTERN void trx_rollback_or_clean_recovered( /*============================*/ ibool all) /*!< in: FALSE=roll back dictionary transactions; TRUE=roll back all non-PREPARED transactions */ { trx_t* trx; ut_a(srv_force_recovery < SRV_FORCE_NO_TRX_UNDO); if (trx_sys_get_n_rw_trx() == 0) { return; } if (all) { fprintf(stderr, "InnoDB: Starting in background the rollback" " of uncommitted transactions\n"); } /* Note: For XA recovered transactions, we rely on MySQL to do rollback. They will be in TRX_STATE_PREPARED state. If the server is shutdown and they are still lingering in trx_sys_t::trx_list then the shutdown will hang. */ /* Loop over the transaction list as long as there are recovered transactions to clean up or recover. */ do { mutex_enter(&trx_sys->mutex); for (trx = UT_LIST_GET_FIRST(trx_sys->rw_trx_list); trx != NULL; trx = UT_LIST_GET_NEXT(trx_list, trx)) { assert_trx_in_rw_list(trx); /* If this function does a cleanup or rollback then it will release the trx_sys->mutex, therefore we need to reacquire it before retrying the loop. */ if (trx_rollback_resurrected(trx, all)) { mutex_enter(&trx_sys->mutex); break; } } mutex_exit(&trx_sys->mutex); } while (trx != NULL); if (all) { ut_print_timestamp(stderr); fprintf(stderr, " InnoDB: Rollback of non-prepared" " transactions completed\n"); } } /*******************************************************************//** Rollback or clean up any incomplete transactions which were encountered in crash recovery. If the transaction already was committed, then we clean up a possible insert undo log. If the transaction was not yet committed, then we roll it back. Note: this is done in a background thread. @return a dummy parameter */ extern "C" UNIV_INTERN os_thread_ret_t DECLARE_THREAD(trx_rollback_or_clean_all_recovered)( /*================================================*/ void* arg __attribute__((unused))) /*!< in: a dummy parameter required by os_thread_create */ { ut_ad(!srv_read_only_mode); #ifdef UNIV_PFS_THREAD pfs_register_thread(trx_rollback_clean_thread_key); #endif /* UNIV_PFS_THREAD */ trx_rollback_or_clean_recovered(TRUE); /* We count the number of threads in os_thread_exit(). A created thread should always use that to exit and not use return() to exit. */ os_thread_exit(NULL); OS_THREAD_DUMMY_RETURN; } /*******************************************************************//** Creates an undo number array. @return own: undo number array */ static trx_undo_arr_t* trx_undo_arr_create( /*================*/ ulint n_cells) /*!< Number of cells */ { trx_undo_arr_t* arr; mem_heap_t* heap; ulint sz = sizeof(*arr) + sizeof(*arr->infos) * n_cells; heap = mem_heap_create(sz); arr = static_cast(mem_heap_zalloc(heap, sz)); arr->n_cells = n_cells; arr->infos = (trx_undo_inf_t*) (arr + 1); arr->heap = heap; return(arr); } /*******************************************************************//** Frees an undo number array. */ UNIV_INTERN void trx_undo_arr_free( /*==============*/ trx_undo_arr_t* arr) /*!< in: undo number array */ { mem_heap_free(arr->heap); } /*******************************************************************//** Stores info of an undo log record to the array if it is not stored yet. @return FALSE if the record already existed in the array */ static ibool trx_undo_arr_store_info( /*====================*/ trx_t* trx, /*!< in: transaction */ undo_no_t undo_no)/*!< in: undo number */ { ulint i; trx_undo_arr_t* arr; ulint n = 0; ulint n_used; trx_undo_inf_t* stored_here = NULL; arr = trx->undo_no_arr; n_used = arr->n_used; for (i = 0; i < arr->n_cells; i++) { trx_undo_inf_t* cell; cell = trx_undo_arr_get_nth_info(arr, i); if (!cell->in_use) { if (!stored_here) { /* Not in use, we may store here */ cell->undo_no = undo_no; cell->in_use = TRUE; arr->n_used++; stored_here = cell; } } else { n++; if (cell->undo_no == undo_no) { if (stored_here) { stored_here->in_use = FALSE; ut_ad(arr->n_used > 0); arr->n_used--; } ut_ad(arr->n_used == n_used); return(FALSE); } } if (n == n_used && stored_here) { ut_ad(arr->n_used == 1 + n_used); return(TRUE); } } ut_error; return(FALSE); } /*******************************************************************//** Removes an undo number from the array. */ static void trx_undo_arr_remove_info( /*=====================*/ trx_undo_arr_t* arr, /*!< in: undo number array */ undo_no_t undo_no)/*!< in: undo number */ { ulint i; for (i = 0; i < arr->n_cells; i++) { trx_undo_inf_t* cell; cell = trx_undo_arr_get_nth_info(arr, i); if (cell->in_use && cell->undo_no == undo_no) { cell->in_use = FALSE; ut_ad(arr->n_used > 0); --arr->n_used; break; } } } /*******************************************************************//** Gets the biggest undo number in an array. @return biggest value, 0 if the array is empty */ static undo_no_t trx_undo_arr_get_biggest( /*=====================*/ const trx_undo_arr_t* arr) /*!< in: undo number array */ { ulint i; undo_no_t biggest = 0; ulint n_checked = 0; for (i = 0; i < arr->n_cells && n_checked < arr->n_used; ++i) { const trx_undo_inf_t* cell = &arr->infos[i]; if (cell->in_use) { ++n_checked; if (cell->undo_no > biggest) { biggest = cell->undo_no; } } } return(biggest); } /***********************************************************************//** Tries truncate the undo logs. */ static void trx_roll_try_truncate( /*==================*/ trx_t* trx) /*!< in/out: transaction */ { undo_no_t limit; const trx_undo_arr_t* arr; ut_ad(mutex_own(&(trx->undo_mutex))); ut_ad(mutex_own(&((trx->rseg)->mutex))); trx->pages_undone = 0; arr = trx->undo_no_arr; limit = trx->undo_no; if (arr->n_used > 0) { undo_no_t biggest; biggest = trx_undo_arr_get_biggest(arr); if (biggest >= limit) { limit = biggest + 1; } } if (trx->insert_undo) { trx_undo_truncate_end(trx, trx->insert_undo, limit); } if (trx->update_undo) { trx_undo_truncate_end(trx, trx->update_undo, limit); } #ifdef WITH_WSREP_OUT if (wsrep_on(trx->mysql_thd)) { trx->lock.was_chosen_as_deadlock_victim = FALSE; } #endif /* WITH_WSREP */ } /***********************************************************************//** Pops the topmost undo log record in a single undo log and updates the info about the topmost record in the undo log memory struct. @return undo log record, the page s-latched */ static trx_undo_rec_t* trx_roll_pop_top_rec( /*=================*/ trx_t* trx, /*!< in: transaction */ trx_undo_t* undo, /*!< in: undo log */ mtr_t* mtr) /*!< in: mtr */ { page_t* undo_page; ulint offset; trx_undo_rec_t* prev_rec; page_t* prev_rec_page; ut_ad(mutex_own(&trx->undo_mutex)); undo_page = trx_undo_page_get_s_latched( undo->space, undo->zip_size, undo->top_page_no, mtr); offset = undo->top_offset; /* fprintf(stderr, "Thread %lu undoing trx " TRX_ID_FMT " undo record " TRX_ID_FMT "\n", os_thread_get_curr_id(), trx->id, undo->top_undo_no); */ prev_rec = trx_undo_get_prev_rec( undo_page + offset, undo->hdr_page_no, undo->hdr_offset, true, mtr); if (prev_rec == NULL) { undo->empty = TRUE; } else { prev_rec_page = page_align(prev_rec); if (prev_rec_page != undo_page) { trx->pages_undone++; } undo->top_page_no = page_get_page_no(prev_rec_page); undo->top_offset = prev_rec - prev_rec_page; undo->top_undo_no = trx_undo_rec_get_undo_no(prev_rec); } return(undo_page + offset); } /********************************************************************//** Pops the topmost record when the two undo logs of a transaction are seen as a single stack of records ordered by their undo numbers. Inserts the undo number of the popped undo record to the array of currently processed undo numbers in the transaction. When the query thread finishes processing of this undo record, it must be released with trx_undo_rec_release. @return undo log record copied to heap, NULL if none left, or if the undo number of the top record would be less than the limit */ UNIV_INTERN trx_undo_rec_t* trx_roll_pop_top_rec_of_trx( /*========================*/ trx_t* trx, /*!< in: transaction */ undo_no_t limit, /*!< in: least undo number we need */ roll_ptr_t* roll_ptr,/*!< out: roll pointer to undo record */ mem_heap_t* heap) /*!< in: memory heap where copied */ { trx_undo_t* undo; trx_undo_t* ins_undo; trx_undo_t* upd_undo; trx_undo_rec_t* undo_rec; trx_undo_rec_t* undo_rec_copy; undo_no_t undo_no; ibool is_insert; trx_rseg_t* rseg; ulint progress_pct; mtr_t mtr; rseg = trx->rseg; try_again: mutex_enter(&(trx->undo_mutex)); if (trx->pages_undone >= TRX_ROLL_TRUNC_THRESHOLD) { mutex_enter(&rseg->mutex); trx_roll_try_truncate(trx); mutex_exit(&rseg->mutex); } ins_undo = trx->insert_undo; upd_undo = trx->update_undo; if (!ins_undo || ins_undo->empty) { undo = upd_undo; } else if (!upd_undo || upd_undo->empty) { undo = ins_undo; } else if (upd_undo->top_undo_no > ins_undo->top_undo_no) { undo = upd_undo; } else { undo = ins_undo; } if (!undo || undo->empty || limit > undo->top_undo_no) { if ((trx->undo_no_arr)->n_used == 0) { /* Rollback is ending */ mutex_enter(&(rseg->mutex)); trx_roll_try_truncate(trx); mutex_exit(&(rseg->mutex)); } mutex_exit(&(trx->undo_mutex)); return(NULL); } is_insert = (undo == ins_undo); *roll_ptr = trx_undo_build_roll_ptr( is_insert, undo->rseg->id, undo->top_page_no, undo->top_offset); mtr_start(&mtr); undo_rec = trx_roll_pop_top_rec(trx, undo, &mtr); undo_no = trx_undo_rec_get_undo_no(undo_rec); ut_ad(undo_no + 1 == trx->undo_no); /* We print rollback progress info if we are in a crash recovery and the transaction has at least 1000 row operations to undo. */ if (trx == trx_roll_crash_recv_trx && trx_roll_max_undo_no > 1000) { progress_pct = 100 - (ulint) ((undo_no * 100) / trx_roll_max_undo_no); if (progress_pct != trx_roll_progress_printed_pct) { if (trx_roll_progress_printed_pct == 0) { fprintf(stderr, "\nInnoDB: Progress in percents:" " %lu", (ulong) progress_pct); } else { fprintf(stderr, " %lu", (ulong) progress_pct); } fflush(stderr); trx_roll_progress_printed_pct = progress_pct; } } trx->undo_no = undo_no; if (!trx_undo_arr_store_info(trx, undo_no)) { /* A query thread is already processing this undo log record */ mutex_exit(&(trx->undo_mutex)); mtr_commit(&mtr); goto try_again; } undo_rec_copy = trx_undo_rec_copy(undo_rec, heap); mutex_exit(&(trx->undo_mutex)); mtr_commit(&mtr); return(undo_rec_copy); } /********************************************************************//** Reserves an undo log record for a query thread to undo. This should be called if the query thread gets the undo log record not using the pop function above. @return TRUE if succeeded */ UNIV_INTERN ibool trx_undo_rec_reserve( /*=================*/ trx_t* trx, /*!< in/out: transaction */ undo_no_t undo_no)/*!< in: undo number of the record */ { ibool ret; mutex_enter(&(trx->undo_mutex)); ret = trx_undo_arr_store_info(trx, undo_no); mutex_exit(&(trx->undo_mutex)); return(ret); } /*******************************************************************//** Releases a reserved undo record. */ UNIV_INTERN void trx_undo_rec_release( /*=================*/ trx_t* trx, /*!< in/out: transaction */ undo_no_t undo_no)/*!< in: undo number */ { trx_undo_arr_t* arr; mutex_enter(&(trx->undo_mutex)); arr = trx->undo_no_arr; trx_undo_arr_remove_info(arr, undo_no); mutex_exit(&(trx->undo_mutex)); } /****************************************************************//** Builds an undo 'query' graph for a transaction. The actual rollback is performed by executing this query graph like a query subprocedure call. The reply about the completion of the rollback will be sent by this graph. @return own: the query graph */ static que_t* trx_roll_graph_build( /*=================*/ trx_t* trx) /*!< in: trx handle */ { mem_heap_t* heap; que_fork_t* fork; que_thr_t* thr; ut_ad(trx_mutex_own(trx)); heap = mem_heap_create(512); fork = que_fork_create(NULL, NULL, QUE_FORK_ROLLBACK, heap); fork->trx = trx; thr = que_thr_create(fork, heap); thr->child = row_undo_node_create(trx, thr, heap); return(fork); } /*********************************************************************//** Starts a rollback operation, creates the UNDO graph that will do the actual undo operation. @return query graph thread that will perform the UNDO operations. */ static que_thr_t* trx_rollback_start( /*===============*/ trx_t* trx, /*!< in: transaction */ ib_id_t roll_limit) /*!< in: rollback to undo no (for partial undo), 0 if we are rolling back the entire transaction */ { que_t* roll_graph; ut_ad(trx_mutex_own(trx)); ut_ad(trx->undo_no_arr == NULL || trx->undo_no_arr->n_used == 0); /* Initialize the rollback field in the transaction */ trx->roll_limit = roll_limit; ut_a(trx->roll_limit <= trx->undo_no); trx->pages_undone = 0; if (trx->undo_no_arr == NULL) { /* Single query thread -> 1 */ trx->undo_no_arr = trx_undo_arr_create(1); } /* Build a 'query' graph which will perform the undo operations */ roll_graph = trx_roll_graph_build(trx); trx->graph = roll_graph; trx->lock.que_state = TRX_QUE_ROLLING_BACK; return(que_fork_start_command(roll_graph)); } /****************************************************************//** Finishes a transaction rollback. */ static void trx_rollback_finish( /*================*/ trx_t* trx) /*!< in: transaction */ { ut_a(trx->undo_no_arr == NULL || trx->undo_no_arr->n_used == 0); trx_commit(trx); trx->lock.que_state = TRX_QUE_RUNNING; } /*********************************************************************//** Creates a rollback command node struct. @return own: rollback node struct */ UNIV_INTERN roll_node_t* roll_node_create( /*=============*/ mem_heap_t* heap) /*!< in: mem heap where created */ { roll_node_t* node; node = static_cast(mem_heap_zalloc(heap, sizeof(*node))); node->state = ROLL_NODE_SEND; node->common.type = QUE_NODE_ROLLBACK; return(node); } /***********************************************************//** Performs an execution step for a rollback command node in a query graph. @return query thread to run next, or NULL */ UNIV_INTERN que_thr_t* trx_rollback_step( /*==============*/ que_thr_t* thr) /*!< in: query thread */ { roll_node_t* node; node = static_cast(thr->run_node); ut_ad(que_node_get_type(node) == QUE_NODE_ROLLBACK); if (thr->prev_node == que_node_get_parent(node)) { node->state = ROLL_NODE_SEND; } if (node->state == ROLL_NODE_SEND) { trx_t* trx; ib_id_t roll_limit = 0; trx = thr_get_trx(thr); trx_mutex_enter(trx); node->state = ROLL_NODE_WAIT; ut_a(node->undo_thr == NULL); roll_limit = node->partial ? node->savept.least_undo_no : 0; trx_commit_or_rollback_prepare(trx); node->undo_thr = trx_rollback_start(trx, roll_limit); trx_mutex_exit(trx); } else { ut_ad(node->state == ROLL_NODE_WAIT); thr->run_node = que_node_get_parent(node); } return(thr); }