mariadb/storage/innobase/trx/trx0trx.cc

/*****************************************************************************

Copyright (c) 1996, 2016, Oracle and/or its affiliates. All Rights Reserved.
Copyright (c) 2015, 2019, MariaDB Corporation.

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, Fifth Floor, Boston, MA 02110-1335 USA

*****************************************************************************/

/**************************************************//**
@file trx/trx0trx.cc
The transaction

Created 3/26/1996 Heikki Tuuri
*******************************************************/

#include "trx0trx.h"

#ifdef WITH_WSREP
#include <mysql/service_wsrep.h>
#endif

#include <mysql/service_thd_error_context.h>

#include "btr0sea.h"
#include "lock0lock.h"
#include "log0log.h"
#include "os0proc.h"
#include "que0que.h"
#include "read0read.h"
#include "srv0mon.h"
#include "srv0srv.h"
#include "srv0start.h"
#include "trx0purge.h"
#include "trx0rec.h"
#include "trx0roll.h"
#include "trx0rseg.h"
#include "trx0undo.h"
#include "trx0xa.h"
#include "ut0pool.h"
#include "ut0vec.h"

#include <set>
#include <new>

extern "C"
int thd_deadlock_victim_preference(const MYSQL_THD thd1, const MYSQL_THD thd2);

static const ulint MAX_DETAILED_ERROR_LEN = 256;

/** Set of table_id */
typedef std::set<
	table_id_t,
	std::less<table_id_t>,
	ut_allocator<table_id_t> >	table_id_set;

/*************************************************************//**
Set detailed error message for the transaction. */
void
trx_set_detailed_error(
/*===================*/
	trx_t*		trx,	/*!< in: transaction struct */
	const char*	msg)	/*!< in: detailed error message */
{
	ut_strlcpy(trx->detailed_error, msg, MAX_DETAILED_ERROR_LEN);
}

/*************************************************************//**
Set detailed error message for the transaction from a file. Note that the
file is rewinded before reading from it. */
void
trx_set_detailed_error_from_file(
/*=============================*/
	trx_t*	trx,	/*!< in: transaction struct */
	FILE*	file)	/*!< in: file to read message from */
{
	os_file_read_string(file, trx->detailed_error, MAX_DETAILED_ERROR_LEN);
}

/********************************************************************//**
Initialize transaction object.
@param trx trx to initialize */
static
void
trx_init(
/*=====*/
	trx_t*	trx)
{
	trx->no = TRX_ID_MAX;

	trx->state = TRX_STATE_NOT_STARTED;

	trx->is_recovered = false;

	trx->op_info = "";

	trx->active_commit_ordered = 0;

	trx->isolation_level = TRX_ISO_REPEATABLE_READ;

	trx->check_foreigns = true;

	trx->check_unique_secondary = true;

	trx->lock.n_rec_locks = 0;

	trx->dict_operation = TRX_DICT_OP_NONE;

	trx->table_id = 0;

	trx->error_state = DB_SUCCESS;

	trx->error_key_num = ULINT_UNDEFINED;

	trx->undo_no = 0;

	trx->rsegs.m_redo.rseg = NULL;

	trx->rsegs.m_noredo.rseg = NULL;

	trx->read_only = false;

	trx->auto_commit = false;

	trx->will_lock = 0;

	trx->ddl = false;

	trx->internal = false;

	ut_d(trx->start_file = 0);

	ut_d(trx->start_line = 0);

	trx->magic_n = TRX_MAGIC_N;

	trx->lock.que_state = TRX_QUE_RUNNING;

	trx->last_sql_stat_start.least_undo_no = 0;

	ut_ad(!MVCC::is_view_active(trx->read_view));

	trx->lock.rec_cached = 0;

	trx->lock.table_cached = 0;

	ut_ad(trx->get_flush_observer() == NULL);
}

/** For managing the life-cycle of the trx_t instance that we get
from the pool. */
struct TrxFactory {

	/** Initializes a transaction object. It must be explicitly started
	with trx_start_if_not_started() before using it. The default isolation
	level is TRX_ISO_REPEATABLE_READ.
	@param trx Transaction instance to initialise */
	static void init(trx_t* trx)
	{
		/* Explicitly call the constructor of the already
		allocated object. trx_t objects are allocated by
		ut_zalloc_nokey() in Pool::Pool() which would not call
		the constructors of the trx_t members. */
		new(&trx->mod_tables) trx_mod_tables_t();

		new(&trx->lock.table_locks) lock_list();

		trx_init(trx);

		trx->dict_operation_lock_mode = 0;

		trx->xid = UT_NEW_NOKEY(xid_t());

		trx->detailed_error = reinterpret_cast<char*>(
			ut_zalloc_nokey(MAX_DETAILED_ERROR_LEN));

		trx->lock.lock_heap = mem_heap_create_typed(
			1024, MEM_HEAP_FOR_LOCK_HEAP);

		lock_trx_lock_list_init(&trx->lock.trx_locks);

		UT_LIST_INIT(
			trx->trx_savepoints,
			&trx_named_savept_t::trx_savepoints);

		mutex_create(LATCH_ID_TRX, &trx->mutex);
		mutex_create(LATCH_ID_TRX_UNDO, &trx->undo_mutex);
	}

	/** Release resources held by the transaction object.
	@param trx the transaction for which to release resources */
	static void destroy(trx_t* trx)
	{
		ut_a(trx->magic_n == TRX_MAGIC_N);
		ut_ad(!trx->in_rw_trx_list);
		ut_ad(!trx->in_mysql_trx_list);

		ut_a(trx->lock.wait_lock == NULL);
		ut_a(trx->lock.wait_thr == NULL);
		ut_a(trx->dict_operation_lock_mode == 0);

		if (trx->lock.lock_heap != NULL) {
			mem_heap_free(trx->lock.lock_heap);
			trx->lock.lock_heap = NULL;
		}

		ut_a(UT_LIST_GET_LEN(trx->lock.trx_locks) == 0);

		UT_DELETE(trx->xid);
		ut_free(trx->detailed_error);

		mutex_free(&trx->mutex);
		mutex_free(&trx->undo_mutex);

		trx->mod_tables.~trx_mod_tables_t();

		ut_ad(trx->read_view == NULL);

		trx->lock.table_locks.~lock_list();
	}

	/** Enforce any invariants here, this is called before the transaction
	is added to the pool.
	@return true if all OK */
	static bool debug(const trx_t* trx)
	{
		ut_a(trx->error_state == DB_SUCCESS);

		ut_a(trx->magic_n == TRX_MAGIC_N);

		ut_ad(!trx->read_only);

		ut_ad(trx->state == TRX_STATE_NOT_STARTED);

		ut_ad(trx->dict_operation == TRX_DICT_OP_NONE);

		ut_ad(trx->mysql_thd == 0);

		ut_ad(!trx->in_rw_trx_list);
		ut_ad(!trx->in_mysql_trx_list);

		ut_a(trx->lock.wait_thr == NULL);
		ut_a(trx->lock.wait_lock == NULL);
		ut_a(trx->dict_operation_lock_mode == 0);

		ut_a(UT_LIST_GET_LEN(trx->lock.trx_locks) == 0);

		ut_ad(trx->autoinc_locks == NULL);

		ut_ad(trx->lock.table_locks.empty());

		return(true);
	}
};

/** The lock strategy for TrxPool */
struct TrxPoolLock {
	TrxPoolLock() { }

	/** Create the mutex */
	void create()
	{
		mutex_create(LATCH_ID_TRX_POOL, &m_mutex);
	}

	/** Acquire the mutex */
	void enter() { mutex_enter(&m_mutex); }

	/** Release the mutex */
	void exit() { mutex_exit(&m_mutex); }

	/** Free the mutex */
	void destroy() { mutex_free(&m_mutex); }

	/** Mutex to use */
	ib_mutex_t	m_mutex;
};

/** The lock strategy for the TrxPoolManager */
struct TrxPoolManagerLock {
	TrxPoolManagerLock() { }

	/** Create the mutex */
	void create()
	{
		mutex_create(LATCH_ID_TRX_POOL_MANAGER, &m_mutex);
	}

	/** Acquire the mutex */
	void enter() { mutex_enter(&m_mutex); }

	/** Release the mutex */
	void exit() { mutex_exit(&m_mutex); }

	/** Free the mutex */
	void destroy() { mutex_free(&m_mutex); }

	/** Mutex to use */
	ib_mutex_t	m_mutex;
};

/** Use explicit mutexes for the trx_t pool and its manager. */
typedef Pool<trx_t, TrxFactory, TrxPoolLock> trx_pool_t;
typedef PoolManager<trx_pool_t, TrxPoolManagerLock > trx_pools_t;

/** The trx_t pool manager */
static trx_pools_t* trx_pools;

/** Size of on trx_t pool in bytes. */
static const ulint MAX_TRX_BLOCK_SIZE = 1024 * 1024 * 4;

/** Create the trx_t pool */
void
trx_pool_init()
{
	trx_pools = UT_NEW_NOKEY(trx_pools_t(MAX_TRX_BLOCK_SIZE));

	ut_a(trx_pools != 0);
}

/** Destroy the trx_t pool */
void
trx_pool_close()
{
	UT_DELETE(trx_pools);

	trx_pools = 0;
}

/** @return a trx_t instance from trx_pools. */
static
trx_t*
trx_create_low()
{
	trx_t*	trx = trx_pools->get();

	assert_trx_is_free(trx);

	mem_heap_t*	heap;
	ib_alloc_t*	alloc;

	/* We just got trx from pool, it should be non locking */
	ut_ad(trx->will_lock == 0);
	ut_ad(trx->state == TRX_STATE_NOT_STARTED);

	DBUG_LOG("trx", "Create: " << trx);

	heap = mem_heap_create(sizeof(ib_vector_t) + sizeof(void*) * 8);

	alloc = ib_heap_allocator_create(heap);

	/* Remember to free the vector explicitly in trx_free(). */
	trx->autoinc_locks = ib_vector_create(alloc, sizeof(void**), 4);

	/* Should have been either just initialized or .clear()ed by
	trx_free(). */
	ut_ad(trx->mod_tables.empty());
	ut_ad(trx->lock.table_locks.empty());
	ut_ad(UT_LIST_GET_LEN(trx->lock.trx_locks) == 0);
	ut_ad(trx->lock.n_rec_locks == 0);
	ut_ad(trx->lock.table_cached == 0);
	ut_ad(trx->lock.rec_cached == 0);

#ifdef WITH_WSREP
	trx->wsrep_event = NULL;
#endif /* WITH_WSREP */

	return(trx);
}

/**
Release a trx_t instance back to the pool.
@param trx the instance to release. */
static
void
trx_free(trx_t*& trx)
{
	assert_trx_is_free(trx);

	trx->mysql_thd = 0;
	trx->mysql_log_file_name = 0;

	// FIXME: We need to avoid this heap free/alloc for each commit.
	if (trx->autoinc_locks != NULL) {
		ut_ad(ib_vector_is_empty(trx->autoinc_locks));
		/* We allocated a dedicated heap for the vector. */
		ib_vector_free(trx->autoinc_locks);
		trx->autoinc_locks = NULL;
	}

	trx->mod_tables.clear();

	ut_ad(trx->read_view == NULL);

	/* trx locking state should have been reset before returning trx
	to pool */
	ut_ad(trx->will_lock == 0);

	trx_pools->mem_free(trx);
	/* Unpoison the memory for innodb_monitor_set_option;
	it is operating also on the freed transaction objects. */
	MEM_UNDEFINED(&trx->mutex, sizeof trx->mutex);
	MEM_UNDEFINED(&trx->undo_mutex, sizeof trx->undo_mutex);
	/* Declare the contents as initialized for Valgrind;
	we checked that it was initialized in trx_pools->mem_free(trx). */
	UNIV_MEM_VALID(&trx->mutex, sizeof trx->mutex);
	UNIV_MEM_VALID(&trx->undo_mutex, sizeof trx->undo_mutex);

	trx = NULL;
}

/********************************************************************//**
Creates a transaction object for background operations by the master thread.
@return own: transaction object */
trx_t*
trx_allocate_for_background(void)
/*=============================*/
{
	trx_t*	trx;

	trx = trx_create_low();

	return(trx);
}

/********************************************************************//**
Creates a transaction object for MySQL.
@return own: transaction object */
trx_t*
trx_allocate_for_mysql(void)
/*========================*/
{
	trx_t*	trx;

	trx = trx_allocate_for_background();

	trx_sys_mutex_enter();

	ut_d(trx->in_mysql_trx_list = TRUE);
	UT_LIST_ADD_FIRST(trx_sys->mysql_trx_list, trx);

	trx_sys_mutex_exit();

	return(trx);
}

/** Check state of transaction before freeing it.
@param trx trx object to validate */
static
void
trx_validate_state_before_free(trx_t* trx)
{
	ut_ad(!trx->declared_to_be_inside_innodb);
	ut_ad(!trx->n_mysql_tables_in_use);
	ut_ad(!trx->mysql_n_tables_locked);
	ut_ad(!trx->internal);

	if (trx->declared_to_be_inside_innodb) {

		ib::error() << "Freeing a trx (" << trx << ", "
			<< trx_get_id_for_print(trx) << ") which is declared"
			" to be processing inside InnoDB";

		trx_print(stderr, trx, 600);
		putc('\n', stderr);

		/* This is an error but not a fatal error. We must keep
		the counters like srv_conc.n_active accurate. */
		srv_conc_force_exit_innodb(trx);
	}

	if (trx->n_mysql_tables_in_use != 0
	    || trx->mysql_n_tables_locked != 0) {

		ib::error() << "MySQL is freeing a thd though"
			" trx->n_mysql_tables_in_use is "
			<< trx->n_mysql_tables_in_use
			<< " and trx->mysql_n_tables_locked is "
			<< trx->mysql_n_tables_locked << ".";

		trx_print(stderr, trx, 600);
		ut_print_buf(stderr, trx, sizeof(trx_t));
		putc('\n', stderr);
	}

	trx->dict_operation = TRX_DICT_OP_NONE;
	assert_trx_is_inactive(trx);
}

/** Free and initialize a transaction object instantinated during recovery.
@param trx trx object to free and initialize during recovery */
void
trx_free_resurrected(trx_t* trx)
{
	trx_validate_state_before_free(trx);

	trx_init(trx);

	trx_free(trx);
}

/** Free a transaction that was allocated by background or user threads.
@param trx trx object to free */
void
trx_free_for_background(trx_t* trx)
{
	trx_validate_state_before_free(trx);

	trx_free(trx);
}

/********************************************************************//**
At shutdown, frees a transaction object that is in the PREPARED state. */
void
trx_free_prepared(
/*==============*/
	trx_t*	trx)	/*!< in, own: trx object */
{
	ut_a(trx_state_eq(trx, TRX_STATE_PREPARED)
	     || trx_state_eq(trx, TRX_STATE_PREPARED_RECOVERED)
	     || (trx->is_recovered
		 && (trx_state_eq(trx, TRX_STATE_ACTIVE)
		     || trx_state_eq(trx, TRX_STATE_COMMITTED_IN_MEMORY))
		 && (!srv_was_started
		     || srv_operation == SRV_OPERATION_RESTORE
		     || srv_operation == SRV_OPERATION_RESTORE_EXPORT
		     || srv_read_only_mode
		     || srv_force_recovery >= SRV_FORCE_NO_TRX_UNDO)));
	ut_a(trx->magic_n == TRX_MAGIC_N);

	lock_trx_release_locks(trx);
	trx_undo_free_prepared(trx);

	assert_trx_in_rw_list(trx);

	ut_a(!trx->read_only);

	ut_d(trx->in_rw_trx_list = FALSE);

	DBUG_LOG("trx", "Free prepared: " << trx);
	trx->state = TRX_STATE_NOT_STARTED;

	/* Undo trx_resurrect_table_locks(). */
	lock_trx_lock_list_init(&trx->lock.trx_locks);

	/* Note: This vector is not guaranteed to be empty because the
	transaction was never committed and therefore lock_trx_release()
	was not called. */
	trx->lock.table_locks.clear();

	trx_free(trx);
}

/** Disconnect a transaction from MySQL and optionally mark it as if
it's been recovered. For the marking the transaction must be in prepared state.
The recovery-marked transaction is going to survive "alone" so its association
with the mysql handle is destroyed now rather than when it will be
finally freed.
@param[in,out]	trx		transaction
@param[in]	prepared	boolean value to specify whether trx is
				for recovery or not. */
inline
void
trx_disconnect_from_mysql(
	trx_t*	trx,
	bool	prepared)
{
	trx_sys_mutex_enter();

	ut_ad(trx->in_mysql_trx_list);
	ut_d(trx->in_mysql_trx_list = FALSE);

	UT_LIST_REMOVE(trx_sys->mysql_trx_list, trx);

	if (trx->read_view != NULL) {
		trx_sys->mvcc->view_close(trx->read_view, true);
	}

	ut_ad(trx_sys_validate_trx_list());

	if (prepared) {

		ut_ad(trx_state_eq(trx, TRX_STATE_PREPARED));

		trx->is_recovered = true;
		trx_sys->n_prepared_recovered_trx++;
	        trx->mysql_thd = NULL;
		/* todo/fixme: suggest to do it at innodb prepare */
		trx->will_lock = 0;
	}

	trx_sys_mutex_exit();
}

/** Disconnect a transaction from MySQL.
@param[in,out]	trx	transaction */
inline
void
trx_disconnect_plain(trx_t*	trx)
{
	trx_disconnect_from_mysql(trx, false);
}

/** Disconnect a prepared transaction from MySQL.
@param[in,out]	trx	transaction */
void
trx_disconnect_prepared(trx_t*	trx)
{
	trx_disconnect_from_mysql(trx, true);
}

/** Free a transaction object for MySQL.
@param[in,out]	trx	transaction */
void
trx_free_for_mysql(trx_t*	trx)
{
	trx_disconnect_plain(trx);
	trx_free_for_background(trx);
}

/****************************************************************//**
Resurrect the table locks for a resurrected transaction. */
static
void
trx_resurrect_table_locks(
/*======================*/
	trx_t*			trx,	/*!< in/out: transaction */
	const trx_undo_ptr_t*	undo_ptr,
					/*!< in: pointer to undo segment. */
	const trx_undo_t*	undo)	/*!< in: undo log */
{
	mtr_t			mtr;
	page_t*			undo_page;
	trx_undo_rec_t*		undo_rec;
	table_id_set		tables;

	ut_ad(undo == undo_ptr->insert_undo || undo == undo_ptr->update_undo);

	if (trx_state_eq(trx, TRX_STATE_COMMITTED_IN_MEMORY) || undo->empty) {

		return;
	}

	mtr_start(&mtr);

	/* trx_rseg_mem_create() may have acquired an X-latch on this
	page, so we cannot acquire an S-latch. */
	undo_page = trx_undo_page_get(
		page_id_t(undo->space, undo->top_page_no), &mtr);

	undo_rec = undo_page + undo->top_offset;

	do {
		ulint		type;
		undo_no_t	undo_no;
		table_id_t	table_id;
		ulint		cmpl_info;
		bool		updated_extern;

		page_t*		undo_rec_page = page_align(undo_rec);

		if (undo_rec_page != undo_page) {
			mtr.release_page(undo_page, MTR_MEMO_PAGE_X_FIX);
			undo_page = undo_rec_page;
		}

		trx_undo_rec_get_pars(
			undo_rec, &type, &cmpl_info,
			&updated_extern, &undo_no, &table_id);
		tables.insert(table_id);

		undo_rec = trx_undo_get_prev_rec(
			undo_rec, undo->hdr_page_no,
			undo->hdr_offset, false, &mtr);
	} while (undo_rec);

	mtr_commit(&mtr);

	for (table_id_set::const_iterator i = tables.begin();
	     i != tables.end(); i++) {
		if (dict_table_t* table = dict_table_open_on_id(
			    *i, FALSE, DICT_TABLE_OP_LOAD_TABLESPACE)) {
			if (!table->is_readable()) {
				mutex_enter(&dict_sys->mutex);
				dict_table_close(table, TRUE, FALSE);
				dict_table_remove_from_cache(table);
				mutex_exit(&dict_sys->mutex);
				continue;
			}

			if (trx->state == TRX_STATE_PREPARED) {
				trx->mod_tables.insert(table);
			}
			lock_table_ix_resurrect(table, trx);

			DBUG_PRINT("ib_trx",
				   ("resurrect" TRX_ID_FMT
				    "  table '%s' IX lock from %s undo",
				    trx_get_id_for_print(trx),
				    table->name.m_name,
				    undo == undo_ptr->insert_undo
				    ? "insert" : "update"));

			dict_table_close(table, FALSE, FALSE);
		}
	}
}

/****************************************************************//**
Resurrect the transactions that were doing inserts the time of the
crash, they need to be undone.
@return trx_t instance */
static
trx_t*
trx_resurrect_insert(
/*=================*/
	trx_undo_t*	undo,		/*!< in: entry to UNDO */
	trx_rseg_t*	rseg)		/*!< in: rollback segment */
{
	trx_t*		trx;

	trx = trx_allocate_for_background();

	ut_d(trx->start_file = __FILE__);
	ut_d(trx->start_line = __LINE__);

	trx->rsegs.m_redo.rseg = rseg;
	*trx->xid = undo->xid;
	trx->id = undo->trx_id;
	trx->rsegs.m_redo.insert_undo = undo;
	trx->is_recovered = true;

	/* This is single-threaded startup code, we do not need the
	protection of trx->mutex or trx_sys->mutex here. */

	if (undo->state != TRX_UNDO_ACTIVE) {

		/* Prepared transactions are left in the prepared state
		waiting for a commit or abort decision from MySQL */

		if (undo->state == TRX_UNDO_PREPARED) {

			ib::info() << "Transaction "
				<< trx_get_id_for_print(trx)
				<< " was in the XA prepared state.";

			trx->state = TRX_STATE_PREPARED;
			trx_sys->n_prepared_trx++;
			trx_sys->n_prepared_recovered_trx++;
		} else {
			trx->state = TRX_STATE_COMMITTED_IN_MEMORY;
		}

		/* We give a dummy value for the trx no; this should have no
		relevance since purge is not interested in committed
		transaction numbers, unless they are in the history
		list, in which case it looks the number from the disk based
		undo log structure */

		trx->no = trx->id;

	} else {
		trx->state = TRX_STATE_ACTIVE;

		/* A running transaction always has the number
		field inited to TRX_ID_MAX */

		trx->no = TRX_ID_MAX;
	}

	/* trx_start_low() is not called with resurrect, so need to initialize
	start time here.*/
	if (trx->state != TRX_STATE_COMMITTED_IN_MEMORY) {
		trx->start_time = ut_time();
	}

	if (undo->dict_operation) {
		trx_set_dict_operation(trx, TRX_DICT_OP_TABLE);
		trx->table_id = undo->table_id;
	}

	if (!undo->empty) {
		trx->undo_no = undo->top_undo_no + 1;
		trx->undo_rseg_space = undo->rseg->space;
	}

	return(trx);
}

/****************************************************************//**
Prepared transactions are left in the prepared state waiting for a
commit or abort decision from MySQL */
static
void
trx_resurrect_update_in_prepared_state(
/*===================================*/
	trx_t*			trx,	/*!< in,out: transaction */
	const trx_undo_t*	undo)	/*!< in: update UNDO record */
{
	/* This is single-threaded startup code, we do not need the
	protection of trx->mutex or trx_sys->mutex here. */

	if (undo->state == TRX_UNDO_PREPARED) {
		ib::info() << "Transaction " << trx_get_id_for_print(trx)
			<< " was in the XA prepared state.";

		if (trx_state_eq(trx, TRX_STATE_NOT_STARTED)) {
			trx_sys->n_prepared_trx++;
			trx_sys->n_prepared_recovered_trx++;
		} else {
			ut_ad(trx_state_eq(trx, TRX_STATE_PREPARED));
		}

		trx->state = TRX_STATE_PREPARED;
	} else {
		trx->state = TRX_STATE_COMMITTED_IN_MEMORY;
	}
}

/****************************************************************//**
Resurrect the transactions that were doing updates the time of the
crash, they need to be undone. */
static
void
trx_resurrect_update(
/*=================*/
	trx_t*		trx,	/*!< in/out: transaction */
	trx_undo_t*	undo,	/*!< in/out: update UNDO record */
	trx_rseg_t*	rseg)	/*!< in/out: rollback segment */
{
	trx->rsegs.m_redo.rseg = rseg;
	*trx->xid = undo->xid;
	trx->id = undo->trx_id;
	trx->rsegs.m_redo.update_undo = undo;
	trx->is_recovered = true;

	/* This is single-threaded startup code, we do not need the
	protection of trx->mutex or trx_sys->mutex here. */

	if (undo->state != TRX_UNDO_ACTIVE) {
		trx_resurrect_update_in_prepared_state(trx, undo);

		/* We give a dummy value for the trx number */

		trx->no = trx->id;

	} else {
		trx->state = TRX_STATE_ACTIVE;

		/* A running transaction always has the number field inited to
		TRX_ID_MAX */

		trx->no = TRX_ID_MAX;
	}

	/* trx_start_low() is not called with resurrect, so need to initialize
	start time here.*/
	if (trx->state == TRX_STATE_ACTIVE
	    || trx->state == TRX_STATE_PREPARED) {
		trx->start_time = ut_time();
	}

	if (undo->dict_operation) {
		trx_set_dict_operation(trx, TRX_DICT_OP_TABLE);
		if (!trx->table_id) {
			trx->table_id = undo->table_id;
		}
	}

	if (!undo->empty && undo->top_undo_no >= trx->undo_no) {

		trx->undo_no = undo->top_undo_no + 1;
		trx->undo_rseg_space = undo->rseg->space;
	}
}

/** Initialize (resurrect) transactions at startup. */
void
trx_lists_init_at_db_start()
{
	ut_a(srv_is_being_started);
	ut_ad(!srv_was_started);
	ut_ad(!purge_sys);

	purge_sys = UT_NEW_NOKEY(purge_sys_t());

	if (srv_force_recovery >= SRV_FORCE_NO_UNDO_LOG_SCAN) {
		return;
	}

	trx_rseg_array_init();

	/* Look from the rollback segments if there exist undo logs for
	transactions. */

	for (ulint i = 0; i < TRX_SYS_N_RSEGS; ++i) {
		trx_undo_t*	undo;
		trx_rseg_t*	rseg = trx_sys->rseg_array[i];

		/* Some rollback segment may be unavailable,
		especially if the server was previously run with a
		non-default value of innodb_undo_logs. */
		if (rseg == NULL) {
			continue;
		}

		/* Resurrect transactions that were doing inserts. */
		for (undo = UT_LIST_GET_FIRST(rseg->insert_undo_list);
		     undo != NULL;
		     undo = UT_LIST_GET_NEXT(undo_list, undo)) {

			/* trx_purge() will not run before we return,
			so we can safely increment this without
			holding rseg->mutex. */
			++rseg->trx_ref_count;

			trx_t*	trx;

			trx = trx_resurrect_insert(undo, rseg);

			trx_sys_rw_trx_add(trx);

			trx_resurrect_table_locks(
				trx, &trx->rsegs.m_redo, undo);
		}

		/* Ressurrect transactions that were doing updates. */
		for (undo = UT_LIST_GET_FIRST(rseg->update_undo_list);
		     undo != NULL;
		     undo = UT_LIST_GET_NEXT(undo_list, undo)) {

			/* Check the trx_sys->rw_trx_set first. */
			trx_sys_mutex_enter();

			trx_t*	trx = trx_get_rw_trx_by_id(undo->trx_id);

			trx_sys_mutex_exit();

			if (trx == NULL) {
				trx = trx_allocate_for_background();
				++rseg->trx_ref_count;

				ut_d(trx->start_file = __FILE__);
				ut_d(trx->start_line = __LINE__);
			}

			trx_resurrect_update(trx, undo, rseg);

			trx_sys_rw_trx_add(trx);

			trx_resurrect_table_locks(
				trx, &trx->rsegs.m_redo, undo);
		}
	}

	TrxIdSet::iterator	end = trx_sys->rw_trx_set.end();

	for (TrxIdSet::iterator it = trx_sys->rw_trx_set.begin();
	     it != end;
	     ++it) {

		ut_ad(it->m_trx->in_rw_trx_list);
#ifdef UNIV_DEBUG
		if (it->m_trx->id > trx_sys->rw_max_trx_id) {
			trx_sys->rw_max_trx_id = it->m_trx->id;
		}
#endif /* UNIV_DEBUG */

		if (it->m_trx->state == TRX_STATE_ACTIVE
		    || it->m_trx->state == TRX_STATE_PREPARED) {

			trx_sys->rw_trx_ids.push_back(it->m_id);
		}

		UT_LIST_ADD_FIRST(trx_sys->rw_trx_list, it->m_trx);
	}
}

/** Assign a persistent rollback segment in a round-robin fashion,
evenly distributed between 0 and innodb_undo_logs-1
@return	persistent rollback segment
@retval	NULL	if innodb_read_only */
static trx_rseg_t* trx_assign_rseg_low()
{
	if (srv_read_only_mode) {
		ut_ad(srv_undo_logs == ULONG_UNDEFINED);
		return(NULL);
	}

	/* The first slot is always assigned to the system tablespace. */
	ut_ad(trx_sys->rseg_array[0]->space == TRX_SYS_SPACE);

	/* Choose a rollback segment evenly distributed between 0 and
	innodb_undo_logs-1 in a round-robin fashion, skipping those
	undo tablespaces that are scheduled for truncation.

	Because rseg_slot is not protected by atomics or any mutex, race
	conditions are possible, meaning that multiple transactions
	that start modifications concurrently will write their undo
	log to the same rollback segment. */
	static ulong	rseg_slot;
	ulint		slot = rseg_slot++ % srv_undo_logs;
	trx_rseg_t*	rseg;

#ifdef UNIV_DEBUG
	ulint	start_scan_slot = slot;
	bool	look_for_rollover = false;
#endif /* UNIV_DEBUG */

	bool	allocated = false;

	do {
		for (;;) {
			rseg = trx_sys->rseg_array[slot];

#ifdef UNIV_DEBUG
			/* Ensure that we are not revisiting the same
			slot that we have already inspected. */
			if (look_for_rollover) {
				ut_ad(start_scan_slot != slot);
			}
			look_for_rollover = true;
#endif /* UNIV_DEBUG */

			slot = (slot + 1) % srv_undo_logs;

			if (rseg == NULL) {
				continue;
			}

			ut_ad(rseg->is_persistent());

			if (rseg->space != TRX_SYS_SPACE) {
				if (rseg->skip_allocation
				    || !srv_undo_tablespaces) {
					continue;
				}
			} else if (trx_rseg_t* next
				   = trx_sys->rseg_array[slot]) {
				if (next->space != TRX_SYS_SPACE
				    && srv_undo_tablespaces > 0) {
					/** If dedicated
					innodb_undo_tablespaces have
					been configured, try to use them
					instead of the system tablespace. */
					continue;
				}
			}

			break;
		}

		/* By now we have only selected the rseg but not marked it
		allocated. By marking it allocated we are ensuring that it will
		never be selected for UNDO truncate purge. */
		mutex_enter(&rseg->mutex);
		if (!rseg->skip_allocation) {
			rseg->trx_ref_count++;
			allocated = true;
		}
		mutex_exit(&rseg->mutex);
	} while (!allocated);

	ut_ad(rseg->trx_ref_count > 0);
	ut_ad(rseg->is_persistent());
	return(rseg);
}

/** Set the innodb_log_optimize_ddl page flush observer
@param[in]	space_id	tablespace id
@param[in,out]	stage		performance_schema accounting */
void trx_t::set_flush_observer(ulint space_id, ut_stage_alter_t* stage)
{
	flush_observer = UT_NEW_NOKEY(FlushObserver(space_id, this, stage));
}

/** Remove the flush observer */
void trx_t::remove_flush_observer()
{
	UT_DELETE(flush_observer);
	flush_observer = NULL;
}

/** Assign a rollback segment for modifying temporary tables.
@return the assigned rollback segment */
trx_rseg_t*
trx_t::assign_temp_rseg()
{
	ut_ad(!rsegs.m_noredo.rseg);
	ut_ad(!trx_is_autocommit_non_locking(this));
	compile_time_assert(ut_is_2pow(TRX_SYS_N_RSEGS));

	/* Choose a temporary rollback segment between 0 and 127
	in a round-robin fashion. Because rseg_slot is not protected by
	atomics or any mutex, race conditions are possible, meaning that
	multiple transactions that start modifications concurrently
	will write their undo log to the same rollback segment. */
	static ulong	rseg_slot;
	trx_rseg_t*	rseg = trx_sys->temp_rsegs[
		rseg_slot++ & (TRX_SYS_N_RSEGS - 1)];
	ut_ad(!rseg->is_persistent());
	rsegs.m_noredo.rseg = rseg;

	if (id == 0) {
		mutex_enter(&trx_sys->mutex);
		id = trx_sys_get_new_trx_id();
		trx_sys->rw_trx_ids.push_back(id);
		trx_sys->rw_trx_set.insert(TrxTrack(id, this));
		mutex_exit(&trx_sys->mutex);
	}

	ut_ad(!rseg->is_persistent());
	return(rseg);
}

/****************************************************************//**
Starts a transaction. */
static
void
trx_start_low(
/*==========*/
	trx_t*	trx,		/*!< in: transaction */
	bool	read_write)	/*!< in: true if read-write transaction */
{
	ut_ad(!trx->in_rollback);
	ut_ad(!trx->is_recovered);
	ut_ad(trx->start_line != 0);
	ut_ad(trx->start_file != 0);
	ut_ad(trx->roll_limit == 0);
	ut_ad(trx->error_state == DB_SUCCESS);
	ut_ad(trx->rsegs.m_redo.rseg == NULL);
	ut_ad(trx->rsegs.m_noredo.rseg == NULL);
	ut_ad(trx_state_eq(trx, TRX_STATE_NOT_STARTED));
	ut_ad(UT_LIST_GET_LEN(trx->lock.trx_locks) == 0);

	/* Check whether it is an AUTOCOMMIT SELECT */
	trx->auto_commit = thd_trx_is_auto_commit(trx->mysql_thd);

	trx->read_only = srv_read_only_mode
		|| (!trx->ddl && !trx->internal
		    && thd_trx_is_read_only(trx->mysql_thd));

	if (!trx->auto_commit) {
		++trx->will_lock;
	} else if (trx->will_lock == 0) {
		trx->read_only = true;
	}

#ifdef WITH_WSREP
	trx->xid->null();
#endif /* WITH_WSREP */

	/* The initial value for trx->no: TRX_ID_MAX is used in
	read_view_open_now: */

	trx->no = TRX_ID_MAX;

	ut_a(ib_vector_is_empty(trx->autoinc_locks));
	ut_a(trx->lock.table_locks.empty());

	/* If this transaction came from trx_allocate_for_mysql(),
	trx->in_mysql_trx_list would hold. In that case, the trx->state
	change must be protected by the trx_sys->mutex, so that
	lock_print_info_all_transactions() will have a consistent view. */

	ut_ad(!trx->in_rw_trx_list);

	/* We tend to over assert and that complicates the code somewhat.
	e.g., the transaction state can be set earlier but we are forced to
	set it under the protection of the trx_sys_t::mutex because some
	trx list assertions are triggered unnecessarily. */

	/* By default all transactions are in the read-only list unless they
	are non-locking auto-commit read only transactions or background
	(internal) transactions. Note: Transactions marked explicitly as
	read only can write to temporary tables, we put those on the RO
	list too. */

	if (!trx->read_only
	    && (trx->mysql_thd == 0 || read_write || trx->ddl)) {

		trx->rsegs.m_redo.rseg = trx_assign_rseg_low();

		/* Temporary rseg is assigned only if the transaction
		updates a temporary table */

		trx_sys_mutex_enter();

		trx->id = trx_sys_get_new_trx_id();

		trx_sys->rw_trx_ids.push_back(trx->id);

		trx_sys_rw_trx_add(trx);

		ut_ad(trx->rsegs.m_redo.rseg != 0
		      || srv_read_only_mode
		      || srv_force_recovery >= SRV_FORCE_NO_TRX_UNDO);

		UT_LIST_ADD_FIRST(trx_sys->rw_trx_list, trx);

		ut_d(trx->in_rw_trx_list = true);
#ifdef UNIV_DEBUG
		if (trx->id > trx_sys->rw_max_trx_id) {
			trx_sys->rw_max_trx_id = trx->id;
		}
#endif /* UNIV_DEBUG */

		trx->state = TRX_STATE_ACTIVE;

		ut_ad(trx_sys_validate_trx_list());

		trx_sys_mutex_exit();
	} else {
		if (!trx_is_autocommit_non_locking(trx)) {

			/* If this is a read-only transaction that is writing
			to a temporary table then it needs a transaction id
			to write to the temporary table. */

			if (read_write) {

				trx_sys_mutex_enter();

				ut_ad(!srv_read_only_mode);

				trx->id = trx_sys_get_new_trx_id();

				trx_sys->rw_trx_ids.push_back(trx->id);

				trx_sys->rw_trx_set.insert(
					TrxTrack(trx->id, trx));

				trx_sys_mutex_exit();
			}

			trx->state = TRX_STATE_ACTIVE;

		} else {
			ut_ad(!read_write);
			trx->state = TRX_STATE_ACTIVE;
		}
	}

	if (trx->mysql_thd != NULL) {
		trx->start_time = thd_start_time_in_secs(trx->mysql_thd);
		trx->start_time_micro = thd_query_start_micro(trx->mysql_thd);

	} else {
		trx->start_time = ut_time();
		trx->start_time_micro = 0;
	}

	ut_a(trx->error_state == DB_SUCCESS);

	MONITOR_INC(MONITOR_TRX_ACTIVE);
}

/** Set the serialisation number for a persistent committed transaction.
@param[in,out]	trx	committed transaction with persistent changes
@param[in,out]	rseg	rollback segment for update_undo, or NULL */
static
void
trx_serialise(trx_t* trx, trx_rseg_t* rseg)
{
	ut_ad(!rseg || rseg == trx->rsegs.m_redo.rseg);

	trx_sys_mutex_enter();

	trx->no = trx_sys_get_new_trx_id();

	/* Track the minimum serialisation number. */
	UT_LIST_ADD_LAST(trx_sys->serialisation_list, trx);

	/* If the rollack segment is not empty then the
	new trx_t::no can't be less than any trx_t::no
	already in the rollback segment. User threads only
	produce events when a rollback segment is empty. */
	if (rseg && rseg->last_page_no == FIL_NULL) {
		TrxUndoRsegs	elem(trx->no);
		elem.push_back(rseg);

		mutex_enter(&purge_sys->pq_mutex);

		/* This is to reduce the pressure on the trx_sys_t::mutex
		though in reality it should make very little (read no)
		difference because this code path is only taken when the
		rbs is empty. */

		trx_sys_mutex_exit();

		purge_sys->purge_queue.push(elem);

		mutex_exit(&purge_sys->pq_mutex);
	} else {
		trx_sys_mutex_exit();
	}
}

/****************************************************************//**
Assign the transaction its history serialisation number and write the
update UNDO log record to the assigned rollback segment.
@return true if a serialisation log was written */
static
bool
trx_write_serialisation_history(
/*============================*/
	trx_t*		trx,	/*!< in/out: transaction */
	mtr_t*		mtr)	/*!< in/out: mini-transaction */
{
	/* Change the undo log segment states from TRX_UNDO_ACTIVE to some
	other state: these modifications to the file data structure define
	the transaction as committed in the file based domain, at the
	serialization point of the log sequence number lsn obtained below. */

	/* We have to hold the rseg mutex because update log headers have
	to be put to the history list in the (serialisation) order of the
	UNDO trx number. This is required for the purge in-memory data
	structures too. */

	if (trx_undo_t* undo = trx->rsegs.m_noredo.undo) {
		/* Undo log for temporary tables is discarded at transaction
		commit. There is no purge for temporary tables, and also no
		MVCC, because they are private to a session. */

		mtr_t	temp_mtr;
		temp_mtr.start();
		temp_mtr.set_log_mode(MTR_LOG_NO_REDO);

		mutex_enter(&trx->rsegs.m_noredo.rseg->mutex);
		trx_undo_set_state_at_finish(undo, &temp_mtr);
		mutex_exit(&trx->rsegs.m_noredo.rseg->mutex);
		temp_mtr.commit();
	}

	if (!trx->rsegs.m_redo.rseg) {
		ut_ad(!trx->rsegs.m_redo.insert_undo);
		ut_ad(!trx->rsegs.m_redo.update_undo);
		return false;
	}

	trx_undo_t* insert = trx->rsegs.m_redo.insert_undo;
	trx_undo_t* update = trx->rsegs.m_redo.update_undo;

	if (!insert && !update) {
		return false;
	}

	ut_ad(!trx->read_only);
	trx_rseg_t*	update_rseg = update ? trx->rsegs.m_redo.rseg : NULL;
	mutex_enter(&trx->rsegs.m_redo.rseg->mutex);

	/* Assign the transaction serialisation number and add any
	update_undo log to the purge queue. */
	trx_serialise(trx, update_rseg);

	/* It is not necessary to acquire trx->undo_mutex here because
	only a single OS thread is allowed to commit this transaction. */
	if (insert) {
		trx_undo_set_state_at_finish(insert, mtr);
	}
	if (update) {
		/* The undo logs and possible delete-marked records
		for updates and deletes will be purged later. */
		page_t*	undo_hdr_page = trx_undo_set_state_at_finish(
			update, mtr);

		trx_undo_update_cleanup(trx, undo_hdr_page, mtr);
	}

	mutex_exit(&trx->rsegs.m_redo.rseg->mutex);

	MONITOR_INC(MONITOR_TRX_COMMIT_UNDO);

	trx_sysf_t* sys_header = trx_sysf_get(mtr);
#ifdef WITH_WSREP
	/* Update latest MySQL wsrep XID in trx sys header. */
	if (wsrep_is_wsrep_xid(trx->xid)) {
		trx_sys_update_wsrep_checkpoint(trx->xid, sys_header, mtr);
	}
#endif /* WITH_WSREP */

	/* Update the latest MySQL binlog name and offset info
	in trx sys header if MySQL binlogging is on or the database
	server is a MySQL replication slave */

	if (trx->mysql_log_file_name != NULL
	    && trx->mysql_log_file_name[0] != '\0') {

		trx_sys_update_mysql_binlog_offset(
			trx->mysql_log_file_name,
			trx->mysql_log_offset,
			sys_header,
			mtr);

		trx->mysql_log_file_name = NULL;
	}

	return(true);
}

/********************************************************************
Finalize a transaction containing updates for a FTS table. */
static
void
trx_finalize_for_fts_table(
/*=======================*/
	fts_trx_table_t*	ftt)	    /* in: FTS trx table */
{
	fts_t*		  fts = ftt->table->fts;
	fts_doc_ids_t*	  doc_ids = ftt->added_doc_ids;

	mutex_enter(&fts->bg_threads_mutex);

	if (fts->fts_status & BG_THREAD_STOP) {
		/* The table is about to be dropped, no use
		adding anything to its work queue. */

		mutex_exit(&fts->bg_threads_mutex);
	} else {
		mem_heap_t*     heap;
		mutex_exit(&fts->bg_threads_mutex);

		ut_a(fts->add_wq);

		heap = static_cast<mem_heap_t*>(doc_ids->self_heap->arg);

		ib_wqueue_add(fts->add_wq, doc_ids, heap);

		/* fts_trx_table_t no longer owns the list. */
		ftt->added_doc_ids = NULL;
	}
}

/******************************************************************//**
Finalize a transaction containing updates to FTS tables. */
static
void
trx_finalize_for_fts(
/*=================*/
	trx_t*	trx,		/*!< in/out: transaction */
	bool	is_commit)	/*!< in: true if the transaction was
				committed, false if it was rolled back. */
{
	if (is_commit) {
		const ib_rbt_node_t*	node;
		ib_rbt_t*		tables;
		fts_savepoint_t*	savepoint;

		savepoint = static_cast<fts_savepoint_t*>(
			ib_vector_last(trx->fts_trx->savepoints));

		tables = savepoint->tables;

		for (node = rbt_first(tables);
		     node;
		     node = rbt_next(tables, node)) {
			fts_trx_table_t**	ftt;

			ftt = rbt_value(fts_trx_table_t*, node);

			if ((*ftt)->added_doc_ids) {
				trx_finalize_for_fts_table(*ftt);
			}
		}
	}

	fts_trx_free(trx->fts_trx);
	trx->fts_trx = NULL;
}

/**********************************************************************//**
If required, flushes the log to disk based on the value of
innodb_flush_log_at_trx_commit. */
static
void
trx_flush_log_if_needed_low(
/*========================*/
	lsn_t	lsn)	/*!< in: lsn up to which logs are to be
			flushed. */
{
	bool	flush = srv_file_flush_method != SRV_NOSYNC;

	switch (srv_flush_log_at_trx_commit) {
	case 3:
	case 2:
		/* Write the log but do not flush it to disk */
		flush = false;
		/* fall through */
	case 1:
		/* Write the log and optionally flush it to disk */
		log_write_up_to(lsn, flush);
		return;
	case 0:
		/* Do nothing */
		return;
	}

	ut_error;
}

/**********************************************************************//**
If required, flushes the log to disk based on the value of
innodb_flush_log_at_trx_commit. */
static
void
trx_flush_log_if_needed(
/*====================*/
	lsn_t	lsn,	/*!< in: lsn up to which logs are to be
			flushed. */
	trx_t*	trx)	/*!< in/out: transaction */
{
	trx->op_info = "flushing log";
	trx_flush_log_if_needed_low(lsn);
	trx->op_info = "";
}

/**********************************************************************//**
For each table that has been modified by the given transaction: update
its dict_table_t::update_time with the current timestamp. Clear the list
of the modified tables at the end. */
static
void
trx_update_mod_tables_timestamp(
/*============================*/
	trx_t*	trx)	/*!< in: transaction */
{

	ut_ad(trx->id != 0);

	/* consider using trx->start_time if calling time() is too
	expensive here */
	time_t	now = ut_time();

	trx_mod_tables_t::const_iterator	end = trx->mod_tables.end();

	for (trx_mod_tables_t::const_iterator it = trx->mod_tables.begin();
	     it != end;
	     ++it) {

		/* This could be executed by multiple threads concurrently
		on the same table object. This is fine because time_t is
		word size or less. And _purely_ _theoretically_, even if
		time_t write is not atomic, likely the value of 'now' is
		the same in all threads and even if it is not, getting a
		"garbage" in table->update_time is justified because
		protecting it with a latch here would be too performance
		intrusive. */
		(*it)->update_time = now;
	}

	trx->mod_tables.clear();
}

/**
Erase the transaction from running transaction lists and serialization
list. Active RW transaction list of a MVCC snapshot(ReadView::prepare)
won't include this transaction after this call. All implicit locks are
also released by this call as trx is removed from rw_trx_list.
@param[in] trx		Transaction to erase, must have an ID > 0
@param[in] serialised	true if serialisation log was written */
static
void
trx_erase_lists(
	trx_t*	trx,
	bool	serialised)
{
	ut_ad(trx->id > 0);
	trx_sys_mutex_enter();

	if (serialised) {
		UT_LIST_REMOVE(trx_sys->serialisation_list, trx);
	}

	trx_ids_t::iterator	it = std::lower_bound(
		trx_sys->rw_trx_ids.begin(),
		trx_sys->rw_trx_ids.end(),
		trx->id);
	ut_ad(*it == trx->id);
	trx_sys->rw_trx_ids.erase(it);

	if (trx->read_only || trx->rsegs.m_redo.rseg == NULL) {

		ut_ad(!trx->in_rw_trx_list);
	} else {

		UT_LIST_REMOVE(trx_sys->rw_trx_list, trx);
		ut_d(trx->in_rw_trx_list = false);
		ut_ad(trx_sys_validate_trx_list());

		if (trx->read_view != NULL) {
			trx_sys->mvcc->view_close(trx->read_view, true);
		}
	}

	trx_sys->rw_trx_set.erase(TrxTrack(trx->id));

	trx_sys_mutex_exit();
}

/****************************************************************//**
Commits a transaction in memory. */
static
void
trx_commit_in_memory(
/*=================*/
	trx_t*		trx,	/*!< in/out: transaction */
	const mtr_t*	mtr,	/*!< in: mini-transaction of
				trx_write_serialisation_history(), or NULL if
				the transaction did not modify anything */
	bool		serialised)
				/*!< in: true if serialisation log was
				written */
{
	trx->must_flush_log_later = false;

	if (trx_is_autocommit_non_locking(trx)) {
		ut_ad(trx->id == 0);
		ut_ad(trx->read_only);
		ut_a(!trx->is_recovered);
		ut_ad(trx->rsegs.m_redo.rseg == NULL);
		ut_ad(!trx->in_rw_trx_list);

		/* Note: We are asserting without holding the lock mutex. But
		that is OK because this transaction is not waiting and cannot
		be rolled back and no new locks can (or should not) be added
		becuase it is flagged as a non-locking read-only transaction. */

		ut_a(UT_LIST_GET_LEN(trx->lock.trx_locks) == 0);

		/* This state change is not protected by any mutex, therefore
		there is an inherent race here around state transition during
		printouts. We ignore this race for the sake of efficiency.
		However, the trx_sys_t::mutex will protect the trx_t instance
		and it cannot be removed from the mysql_trx_list and freed
		without first acquiring the trx_sys_t::mutex. */

		ut_ad(trx_state_eq(trx, TRX_STATE_ACTIVE));

		if (trx->read_view != NULL) {
			trx_sys->mvcc->view_close(trx->read_view, false);
		}

		MONITOR_INC(MONITOR_TRX_NL_RO_COMMIT);

		DBUG_LOG("trx", "Autocommit in memory: " << trx);
		trx->state = TRX_STATE_NOT_STARTED;
	} else {
		if (trx->id > 0) {
			/* For consistent snapshot, we need to remove current
			transaction from running transaction id list for mvcc
			before doing commit and releasing locks. */
			trx_erase_lists(trx, serialised);
		}

		/* trx->id will be cleared in lock_trx_release_locks(trx). */
		ut_ad(trx->read_only || !trx->rsegs.m_redo.rseg || trx->id);
		lock_trx_release_locks(trx);
		ut_ad(trx->id == 0);

		/* Remove the transaction from the list of active
		transactions now that it no longer holds any user locks. */

		ut_ad(trx_state_eq(trx, TRX_STATE_COMMITTED_IN_MEMORY));
		DEBUG_SYNC_C("after_trx_committed_in_memory");

		if (trx->read_only || trx->rsegs.m_redo.rseg == NULL) {

			MONITOR_INC(MONITOR_TRX_RO_COMMIT);
			if (trx->read_view != NULL) {
				trx_sys->mvcc->view_close(
					trx->read_view, false);
			}

		} else {
			MONITOR_INC(MONITOR_TRX_RW_COMMIT);
		}
	}

	ut_ad(!trx->rsegs.m_redo.update_undo);

	if (trx_rseg_t*	rseg = trx->rsegs.m_redo.rseg) {
		mutex_enter(&rseg->mutex);
		ut_ad(rseg->trx_ref_count > 0);
		--rseg->trx_ref_count;
		mutex_exit(&rseg->mutex);

		if (trx_undo_t*& insert = trx->rsegs.m_redo.insert_undo) {
			ut_ad(insert->rseg == rseg);
			trx_undo_commit_cleanup(insert, false);
			insert = NULL;
		}
	}

	ut_ad(!trx->rsegs.m_redo.insert_undo);

	if (mtr != NULL) {
		if (trx_undo_t*& undo = trx->rsegs.m_noredo.undo) {
			ut_ad(undo->rseg == trx->rsegs.m_noredo.rseg);
			trx_undo_commit_cleanup(undo, true);
			undo = NULL;
		}

		/* NOTE that we could possibly make a group commit more
		efficient here: call os_thread_yield here to allow also other
		trxs to come to commit! */

		/*-------------------------------------*/

		/* Depending on the my.cnf options, we may now write the log
		buffer to the log files, making the transaction durable if
		the OS does not crash. We may also flush the log files to
		disk, making the transaction durable also at an OS crash or a
		power outage.

		The idea in InnoDB's group commit is that a group of
		transactions gather behind a trx doing a physical disk write
		to log files, and when that physical write has been completed,
		one of those transactions does a write which commits the whole
		group. Note that this group commit will only bring benefit if
		there are > 2 users in the database. Then at least 2 users can
		gather behind one doing the physical log write to disk.

		If we are calling trx_commit() under prepare_commit_mutex, we
		will delay possible log write and flush to a separate function
		trx_commit_complete_for_mysql(), which is only called when the
		thread has released the mutex. This is to make the
		group commit algorithm to work. Otherwise, the prepare_commit
		mutex would serialize all commits and prevent a group of
		transactions from gathering. */

		lsn_t	lsn = mtr->commit_lsn();

		if (lsn == 0) {
			/* Nothing to be done. */
		} else if (trx->flush_log_later) {
			/* Do nothing yet */
			trx->must_flush_log_later = true;
		} else if (srv_flush_log_at_trx_commit == 0) {
			/* Do nothing */
		} else {
			trx_flush_log_if_needed(lsn, trx);
		}

		trx->commit_lsn = lsn;

		/* Tell server some activity has happened, since the trx
		does changes something. Background utility threads like
		master thread, purge thread or page_cleaner thread might
		have some work to do. */
		srv_active_wake_master_thread();
	}

	ut_ad(!trx->rsegs.m_noredo.undo);

	/* Free all savepoints, starting from the first. */
	trx_named_savept_t*	savep = UT_LIST_GET_FIRST(trx->trx_savepoints);

	trx_roll_savepoints_free(trx, savep);

        if (trx->fts_trx != NULL) {
                trx_finalize_for_fts(trx, trx->undo_no != 0);
        }

	trx_mutex_enter(trx);
	trx->dict_operation = TRX_DICT_OP_NONE;

#ifdef WITH_WSREP
	if (trx->mysql_thd && wsrep_on(trx->mysql_thd)) {
		trx->lock.was_chosen_as_deadlock_victim = FALSE;
	}
#endif

	DBUG_LOG("trx", "Commit in memory: " << trx);
	trx->state = TRX_STATE_NOT_STARTED;

	/* trx->in_mysql_trx_list would hold between
	trx_allocate_for_mysql() and trx_free_for_mysql(). It does not
	hold for recovered transactions or system transactions. */
	assert_trx_is_free(trx);

	trx_init(trx);

	trx_mutex_exit(trx);

	ut_a(trx->error_state == DB_SUCCESS);
	srv_wake_purge_thread_if_not_active();
}

/****************************************************************//**
Commits a transaction and a mini-transaction. */
void
trx_commit_low(
/*===========*/
	trx_t*	trx,	/*!< in/out: transaction */
	mtr_t*	mtr)	/*!< in/out: mini-transaction (will be committed),
			or NULL if trx made no modifications */
{
	assert_trx_nonlocking_or_in_list(trx);
	ut_ad(!trx_state_eq(trx, TRX_STATE_COMMITTED_IN_MEMORY));
	ut_ad(!mtr || mtr->is_active());
	ut_ad(!mtr == !trx->has_logged());

	/* undo_no is non-zero if we're doing the final commit. */
	if (trx->fts_trx != NULL && trx->undo_no != 0) {
		dberr_t	error;

		ut_a(!trx_is_autocommit_non_locking(trx));

		error = fts_commit(trx);

		/* FTS-FIXME: Temporarily tolerate DB_DUPLICATE_KEY
		instead of dying. This is a possible scenario if there
		is a crash between insert to DELETED table committing
		and transaction committing. The fix would be able to
		return error from this function */
		if (error != DB_SUCCESS && error != DB_DUPLICATE_KEY) {
			/* FTS-FIXME: once we can return values from this
			function, we should do so and signal an error
			instead of just dying. */

			ut_error;
		}
	}

	bool	serialised;

	if (mtr != NULL) {
		serialised = trx_write_serialisation_history(trx, mtr);

		/* The following call commits the mini-transaction, making the
		whole transaction committed in the file-based world, at this
		log sequence number. The transaction becomes 'durable' when
		we write the log to disk, but in the logical sense the commit
		in the file-based data structures (undo logs etc.) happens
		here.

		NOTE that transaction numbers, which are assigned only to
		transactions with an update undo log, do not necessarily come
		in exactly the same order as commit lsn's, if the transactions
		have different rollback segments. To get exactly the same
		order we should hold the kernel mutex up to this point,
		adding to the contention of the kernel mutex. However, if
		a transaction T2 is able to see modifications made by
		a transaction T1, T2 will always get a bigger transaction
		number and a bigger commit lsn than T1. */

		/*--------------*/
		mtr_commit(mtr);

		DBUG_EXECUTE_IF("ib_crash_during_trx_commit_in_mem",
				if (trx->has_logged()) {
					log_write_up_to(mtr->commit_lsn(),
							true);
					DBUG_SUICIDE();
				});
		/*--------------*/

	} else {
		serialised = false;
	}
#ifndef DBUG_OFF
	/* In case of this function is called from a stack executing
	   THD::release_resources -> ...
              innobase_connection_close() ->
                     trx_rollback_for_mysql... -> .
           mysql's thd does not seem to have
           thd->debug_sync_control defined any longer. However the stack
           is possible only with a prepared trx not updating any data.
        */
	if (trx->mysql_thd != NULL && trx->has_logged_persistent()) {
		DEBUG_SYNC_C("before_trx_state_committed_in_memory");
	}
#endif

	trx_commit_in_memory(trx, mtr, serialised);
}

/****************************************************************//**
Commits a transaction. */
void
trx_commit(
/*=======*/
	trx_t*	trx)	/*!< in/out: transaction */
{
	mtr_t*	mtr;
	mtr_t	local_mtr;

	DBUG_EXECUTE_IF("ib_trx_commit_crash_before_trx_commit_start",
			DBUG_SUICIDE(););

	if (trx->has_logged()) {
		mtr = &local_mtr;
		mtr->start();
	} else {

		mtr = NULL;
	}

	trx_commit_low(trx, mtr);
}

/****************************************************************//**
Cleans up a transaction at database startup. The cleanup is needed if
the transaction already got to the middle of a commit when the database
crashed, and we cannot roll it back. */
void
trx_cleanup_at_db_startup(
/*======================*/
	trx_t*	trx)	/*!< in: transaction */
{
	ut_ad(trx->is_recovered);
	ut_ad(!trx->rsegs.m_noredo.undo);
	ut_ad(!trx->rsegs.m_redo.update_undo);

	if (trx_undo_t*& undo = trx->rsegs.m_redo.insert_undo) {
		ut_ad(undo->rseg == trx->rsegs.m_redo.rseg);
		trx_undo_commit_cleanup(undo, false);
		undo = NULL;
	}

	memset(&trx->rsegs, 0x0, sizeof(trx->rsegs));
	trx->undo_no = 0;
	trx->undo_rseg_space = 0;
	trx->last_sql_stat_start.least_undo_no = 0;

	trx_sys_mutex_enter();

	ut_a(!trx->read_only);

	UT_LIST_REMOVE(trx_sys->rw_trx_list, trx);

	ut_d(trx->in_rw_trx_list = FALSE);

	trx_sys_mutex_exit();

	/* Change the transaction state without mutex protection, now
	that it no longer is in the trx_list. Recovered transactions
	are never placed in the mysql_trx_list. */
	ut_ad(trx->is_recovered);
	ut_ad(!trx->in_rw_trx_list);
	ut_ad(!trx->in_mysql_trx_list);
	DBUG_LOG("trx", "Cleanup at startup: " << trx);
	trx->id = 0;
	trx->state = TRX_STATE_NOT_STARTED;
}

/********************************************************************//**
Assigns a read view for a consistent read query. All the consistent reads
within the same transaction will get the same read view, which is created
when this function is first called for a new started transaction.
@return consistent read view */
ReadView*
trx_assign_read_view(
/*=================*/
	trx_t*		trx)	/*!< in/out: active transaction */
{
	ut_ad(trx->state == TRX_STATE_ACTIVE);

	if (srv_read_only_mode) {

		ut_ad(trx->read_view == NULL);
		return(NULL);

	} else if (!MVCC::is_view_active(trx->read_view)) {
		trx_sys->mvcc->view_open(trx->read_view, trx);
	}

	return(trx->read_view);
}

/****************************************************************//**
Prepares a transaction for commit/rollback. */
void
trx_commit_or_rollback_prepare(
/*===========================*/
	trx_t*	trx)		/*!< in/out: transaction */
{
	/* We are reading trx->state without holding trx_sys->mutex
	here, because the commit or rollback should be invoked for a
	running (or recovered prepared) transaction that is associated
	with the current thread. */

	switch (trx->state) {
	case TRX_STATE_NOT_STARTED:
		trx_start_low(trx, true);
		/* fall through */

	case TRX_STATE_ACTIVE:
	case TRX_STATE_PREPARED:
	case TRX_STATE_PREPARED_RECOVERED:
		/* If the trx is in a lock wait state, moves the waiting
		query thread to the suspended state */

		if (trx->lock.que_state == TRX_QUE_LOCK_WAIT) {

			ut_a(trx->lock.wait_thr != NULL);
			trx->lock.wait_thr->state = QUE_THR_SUSPENDED;
			trx->lock.wait_thr = NULL;

			trx->lock.que_state = TRX_QUE_RUNNING;
		}

		ut_a(trx->lock.n_active_thrs == 1);
		return;

	case TRX_STATE_COMMITTED_IN_MEMORY:
		break;
	}

	ut_error;
}

/*********************************************************************//**
Creates a commit command node struct.
@return own: commit node struct */
commit_node_t*
trx_commit_node_create(
/*===================*/
	mem_heap_t*	heap)	/*!< in: mem heap where created */
{
	commit_node_t*	node;

	node = static_cast<commit_node_t*>(mem_heap_alloc(heap, sizeof(*node)));
	node->common.type  = QUE_NODE_COMMIT;
	node->state = COMMIT_NODE_SEND;

	return(node);
}

/***********************************************************//**
Performs an execution step for a commit type node in a query graph.
@return query thread to run next, or NULL */
que_thr_t*
trx_commit_step(
/*============*/
	que_thr_t*	thr)	/*!< in: query thread */
{
	commit_node_t*	node;

	node = static_cast<commit_node_t*>(thr->run_node);

	ut_ad(que_node_get_type(node) == QUE_NODE_COMMIT);

	if (thr->prev_node == que_node_get_parent(node)) {
		node->state = COMMIT_NODE_SEND;
	}

	if (node->state == COMMIT_NODE_SEND) {
		trx_t*	trx;

		node->state = COMMIT_NODE_WAIT;

		trx = thr_get_trx(thr);

		ut_a(trx->lock.wait_thr == NULL);
		ut_a(trx->lock.que_state != TRX_QUE_LOCK_WAIT);

		trx_commit_or_rollback_prepare(trx);

		trx->lock.que_state = TRX_QUE_COMMITTING;

		trx_commit(trx);

		ut_ad(trx->lock.wait_thr == NULL);

		trx->lock.que_state = TRX_QUE_RUNNING;

		thr = NULL;
	} else {
		ut_ad(node->state == COMMIT_NODE_WAIT);

		node->state = COMMIT_NODE_SEND;

		thr->run_node = que_node_get_parent(node);
	}

	return(thr);
}

/**********************************************************************//**
Does the transaction commit for MySQL.
@return DB_SUCCESS or error number */
dberr_t
trx_commit_for_mysql(
/*=================*/
	trx_t*	trx)	/*!< in/out: transaction */
{
	/* Because we do not do the commit by sending an Innobase
	sig to the transaction, we must here make sure that trx has been
	started. */

	switch (trx->state) {
	case TRX_STATE_NOT_STARTED:
		ut_d(trx->start_file = __FILE__);
		ut_d(trx->start_line = __LINE__);

		trx_start_low(trx, true);
		/* fall through */
	case TRX_STATE_ACTIVE:
	case TRX_STATE_PREPARED:
	case TRX_STATE_PREPARED_RECOVERED:
		trx->op_info = "committing";

		if (trx->id != 0) {
			trx_update_mod_tables_timestamp(trx);
		}

		trx_commit(trx);

		MONITOR_DEC(MONITOR_TRX_ACTIVE);
		trx->op_info = "";
		return(DB_SUCCESS);
	case TRX_STATE_COMMITTED_IN_MEMORY:
		break;
	}
	ut_error;
	return(DB_CORRUPTION);
}

/**********************************************************************//**
If required, flushes the log to disk if we called trx_commit_for_mysql()
with trx->flush_log_later == TRUE. */
void
trx_commit_complete_for_mysql(
/*==========================*/
	trx_t*	trx)	/*!< in/out: transaction */
{
	if (trx->id != 0
	    || !trx->must_flush_log_later
	    || (srv_flush_log_at_trx_commit == 1 && trx->active_commit_ordered)) {

		return;
	}

	trx_flush_log_if_needed(trx->commit_lsn, trx);

	trx->must_flush_log_later = false;
}

/**********************************************************************//**
Marks the latest SQL statement ended. */
void
trx_mark_sql_stat_end(
/*==================*/
	trx_t*	trx)	/*!< in: trx handle */
{
	ut_a(trx);

	switch (trx->state) {
	case TRX_STATE_PREPARED:
	case TRX_STATE_PREPARED_RECOVERED:
	case TRX_STATE_COMMITTED_IN_MEMORY:
		break;
	case TRX_STATE_NOT_STARTED:
		trx->undo_no = 0;
		trx->undo_rseg_space = 0;
		/* fall through */
	case TRX_STATE_ACTIVE:
		trx->last_sql_stat_start.least_undo_no = trx->undo_no;

		if (trx->fts_trx != NULL) {
			fts_savepoint_laststmt_refresh(trx);
		}

		return;
	}

	ut_error;
}

/**********************************************************************//**
Prints info about a transaction.
Caller must hold trx_sys->mutex. */
void
trx_print_low(
/*==========*/
	FILE*		f,
			/*!< in: output stream */
	const trx_t*	trx,
			/*!< in: transaction */
	ulint		max_query_len,
			/*!< in: max query length to print,
			or 0 to use the default max length */
	ulint		n_rec_locks,
			/*!< in: lock_number_of_rows_locked(&trx->lock) */
	ulint		n_trx_locks,
			/*!< in: length of trx->lock.trx_locks */
	ulint		heap_size)
			/*!< in: mem_heap_get_size(trx->lock.lock_heap) */
{
	ibool		newline;
	const char*	op_info;

	ut_ad(trx_sys_mutex_own());

	fprintf(f, "TRANSACTION " TRX_ID_FMT, trx_get_id_for_print(trx));

	/* trx->state cannot change from or to NOT_STARTED while we
	are holding the trx_sys->mutex. It may change from ACTIVE to
	PREPARED or COMMITTED. */
	switch (trx->state) {
	case TRX_STATE_NOT_STARTED:
		fputs(", not started", f);
		goto state_ok;
	case TRX_STATE_ACTIVE:
		fprintf(f, ", ACTIVE %lu sec",
			(ulong) difftime(time(NULL), trx->start_time));
		goto state_ok;
	case TRX_STATE_PREPARED:
	case TRX_STATE_PREPARED_RECOVERED:
		fprintf(f, ", ACTIVE (PREPARED) %lu sec",
			(ulong) difftime(time(NULL), trx->start_time));
		goto state_ok;
	case TRX_STATE_COMMITTED_IN_MEMORY:
		fputs(", COMMITTED IN MEMORY", f);
		goto state_ok;
	}
	fprintf(f, ", state %lu", (ulong) trx->state);
	ut_ad(0);
state_ok:

	/* prevent a race condition */
	op_info = trx->op_info;

	if (*op_info) {
		putc(' ', f);
		fputs(op_info, f);
	}

	if (trx->is_recovered) {
		fputs(" recovered trx", f);
	}

	if (trx->declared_to_be_inside_innodb) {
		fprintf(f, ", thread declared inside InnoDB %lu",
			(ulong) trx->n_tickets_to_enter_innodb);
	}

	putc('\n', f);

	if (trx->n_mysql_tables_in_use > 0 || trx->mysql_n_tables_locked > 0) {
		fprintf(f, "mysql tables in use %lu, locked %lu\n",
			(ulong) trx->n_mysql_tables_in_use,
			(ulong) trx->mysql_n_tables_locked);
	}

	newline = TRUE;

	/* trx->lock.que_state of an ACTIVE transaction may change
	while we are not holding trx->mutex. We perform a dirty read
	for performance reasons. */

	switch (trx->lock.que_state) {
	case TRX_QUE_RUNNING:
		newline = FALSE; break;
	case TRX_QUE_LOCK_WAIT:
		fputs("LOCK WAIT ", f); break;
	case TRX_QUE_ROLLING_BACK:
		fputs("ROLLING BACK ", f); break;
	case TRX_QUE_COMMITTING:
		fputs("COMMITTING ", f); break;
	default:
		fprintf(f, "que state %lu ", (ulong) trx->lock.que_state);
	}

	if (n_trx_locks > 0 || heap_size > 400) {
		newline = TRUE;

		fprintf(f, "%lu lock struct(s), heap size %lu,"
			" %lu row lock(s)",
			(ulong) n_trx_locks,
			(ulong) heap_size,
			(ulong) n_rec_locks);
	}

	if (trx->undo_no != 0) {
		newline = TRUE;
		fprintf(f, ", undo log entries " TRX_ID_FMT, trx->undo_no);
	}

	if (newline) {
		putc('\n', f);
	}

	if (trx->state != TRX_STATE_NOT_STARTED && trx->mysql_thd != NULL) {
		innobase_mysql_print_thd(
			f, trx->mysql_thd, static_cast<uint>(max_query_len));
	}
}

/**********************************************************************//**
Prints info about a transaction.
The caller must hold lock_sys->mutex and trx_sys->mutex.
When possible, use trx_print() instead. */
void
trx_print_latched(
/*==============*/
	FILE*		f,		/*!< in: output stream */
	const trx_t*	trx,		/*!< in: transaction */
	ulint		max_query_len)	/*!< in: max query length to print,
					or 0 to use the default max length */
{
	ut_ad(lock_mutex_own());
	ut_ad(trx_sys_mutex_own());

	trx_print_low(f, trx, max_query_len,
		      lock_number_of_rows_locked(&trx->lock),
		      UT_LIST_GET_LEN(trx->lock.trx_locks),
		      mem_heap_get_size(trx->lock.lock_heap));
}

#ifdef WITH_WSREP
/**********************************************************************//**
Prints info about a transaction.
Transaction information may be retrieved without having trx_sys->mutex acquired
so it may not be completely accurate. The caller must own lock_sys->mutex
and the trx must have some locks to make sure that it does not escape
without locking lock_sys->mutex. */
UNIV_INTERN
void
wsrep_trx_print_locking(
	FILE*		f,
			/*!< in: output stream */
	const trx_t*	trx,
			/*!< in: transaction */
	ulint		max_query_len)
			/*!< in: max query length to print,
			or 0 to use the default max length */
{
	ibool		newline;
	const char*	op_info;

	ut_ad(lock_mutex_own());
	ut_ad(trx->lock.trx_locks.count > 0);

	fprintf(f, "TRANSACTION " TRX_ID_FMT, trx->id);

	/* trx->state may change since trx_sys->mutex is not required */
	switch (trx->state) {
	case TRX_STATE_NOT_STARTED:
		fputs(", not started", f);
		goto state_ok;
	case TRX_STATE_ACTIVE:
		fprintf(f, ", ACTIVE %lu sec",
			(ulong) difftime(time(NULL), trx->start_time));
		goto state_ok;
	case TRX_STATE_PREPARED:
	case TRX_STATE_PREPARED_RECOVERED:
		fprintf(f, ", ACTIVE (PREPARED) %lu sec",
			(ulong) difftime(time(NULL), trx->start_time));
		goto state_ok;
	case TRX_STATE_COMMITTED_IN_MEMORY:
		fputs(", COMMITTED IN MEMORY", f);
		goto state_ok;
	}
	fprintf(f, ", state %lu", (ulong) trx->state);
	ut_ad(0);
state_ok:

	/* prevent a race condition */
	op_info = trx->op_info;

	if (*op_info) {
		putc(' ', f);
		fputs(op_info, f);
	}

	if (trx->is_recovered) {
		fputs(" recovered trx", f);
	}

	if (trx->declared_to_be_inside_innodb) {
		fprintf(f, ", thread declared inside InnoDB %lu",
			(ulong) trx->n_tickets_to_enter_innodb);
	}

	putc('\n', f);

	if (trx->n_mysql_tables_in_use > 0 || trx->mysql_n_tables_locked > 0) {
		fprintf(f, "mysql tables in use %lu, locked %lu\n",
			(ulong) trx->n_mysql_tables_in_use,
			(ulong) trx->mysql_n_tables_locked);
	}

	newline = TRUE;

	/* trx->lock.que_state of an ACTIVE transaction may change
	while we are not holding trx->mutex. We perform a dirty read
	for performance reasons. */

	switch (trx->lock.que_state) {
	case TRX_QUE_RUNNING:
		newline = FALSE; break;
	case TRX_QUE_LOCK_WAIT:
		fputs("LOCK WAIT ", f); break;
	case TRX_QUE_ROLLING_BACK:
		fputs("ROLLING BACK ", f); break;
	case TRX_QUE_COMMITTING:
		fputs("COMMITTING ", f); break;
	default:
		fprintf(f, "que state %lu ", (ulong) trx->lock.que_state);
	}

	if (trx->undo_no != 0) {
		newline = TRUE;
		fprintf(f, ", undo log entries " TRX_ID_FMT, trx->undo_no);
	}

	if (newline) {
		putc('\n', f);
	}

	if (trx->mysql_thd != NULL) {
		innobase_mysql_print_thd(
			f, trx->mysql_thd, static_cast<uint>(max_query_len));
	}
}
#endif /* WITH_WSREP */
/**********************************************************************//**
Prints info about a transaction.
Acquires and releases lock_sys->mutex and trx_sys->mutex. */
void
trx_print(
/*======*/
	FILE*		f,		/*!< in: output stream */
	const trx_t*	trx,		/*!< in: transaction */
	ulint		max_query_len)	/*!< in: max query length to print,
					or 0 to use the default max length */
{
	ulint	n_rec_locks;
	ulint	n_trx_locks;
	ulint	heap_size;

	lock_mutex_enter();
	n_rec_locks = lock_number_of_rows_locked(&trx->lock);
	n_trx_locks = UT_LIST_GET_LEN(trx->lock.trx_locks);
	heap_size = mem_heap_get_size(trx->lock.lock_heap);
	lock_mutex_exit();

	mutex_enter(&trx_sys->mutex);

	trx_print_low(f, trx, max_query_len,
		      n_rec_locks, n_trx_locks, heap_size);

	mutex_exit(&trx_sys->mutex);
}

#ifdef UNIV_DEBUG
/**********************************************************************//**
Asserts that a transaction has been started.
The caller must hold trx_sys->mutex.
@return TRUE if started */
ibool
trx_assert_started(
/*===============*/
	const trx_t*	trx)	/*!< in: transaction */
{
	ut_ad(trx_sys_mutex_own());

	/* Non-locking autocommits should not hold any locks and this
	function is only called from the locking code. */
	check_trx_state(trx);

	/* trx->state can change from or to NOT_STARTED while we are holding
	trx_sys->mutex for non-locking autocommit selects but not for other
	types of transactions. It may change from ACTIVE to PREPARED. Unless
	we are holding lock_sys->mutex, it may also change to COMMITTED. */

	switch (trx->state) {
	case TRX_STATE_PREPARED:
	case TRX_STATE_PREPARED_RECOVERED:
		return(TRUE);

	case TRX_STATE_ACTIVE:
	case TRX_STATE_COMMITTED_IN_MEMORY:
		return(TRUE);

	case TRX_STATE_NOT_STARTED:
		break;
	}

	ut_error;
	return(FALSE);
}
#endif /* UNIV_DEBUG */

/*******************************************************************//**
Compares the "weight" (or size) of two transactions. Transactions that
have edited non-transactional tables are considered heavier than ones
that have not.
@return TRUE if weight(a) >= weight(b) */
bool
trx_weight_ge(
/*==========*/
	const trx_t*	a,	/*!< in: transaction to be compared */
	const trx_t*	b)	/*!< in: transaction to be compared */
{
	ibool	a_notrans_edit;
	ibool	b_notrans_edit;

	/* If mysql_thd is NULL for a transaction we assume that it has
	not edited non-transactional tables. */

	a_notrans_edit = a->mysql_thd != NULL
		&& thd_has_edited_nontrans_tables(a->mysql_thd);

	b_notrans_edit = b->mysql_thd != NULL
		&& thd_has_edited_nontrans_tables(b->mysql_thd);

	if (a_notrans_edit != b_notrans_edit) {

		return(a_notrans_edit);
	}

	/* Either both had edited non-transactional tables or both had
	not, we fall back to comparing the number of altered/locked
	rows. */

	return(TRX_WEIGHT(a) >= TRX_WEIGHT(b));
}

/** Prepare a transaction.
@return	log sequence number that makes the XA PREPARE durable
@retval	0	if no changes needed to be made durable */
static
lsn_t
trx_prepare_low(trx_t* trx)
{
	mtr_t	mtr;

	/* It is not necessary to acquire trx->undo_mutex here because
	only the owning (connection) thread of the transaction is
	allowed to perform XA PREPARE. */

	if (trx_undo_t* undo = trx->rsegs.m_noredo.undo) {
		ut_ad(undo->rseg == trx->rsegs.m_noredo.rseg);

		mtr.start();
		mtr.set_log_mode(MTR_LOG_NO_REDO);

		mutex_enter(&undo->rseg->mutex);
		trx_undo_set_state_at_prepare(trx, undo, false, &mtr);
		mutex_exit(&undo->rseg->mutex);

		mtr.commit();
	}

	trx_undo_t* insert = trx->rsegs.m_redo.insert_undo;
	trx_undo_t* update = trx->rsegs.m_redo.update_undo;

	if (!insert && !update) {
		/* There were no changes to persistent tables. */
		return(0);
	}

	trx_rseg_t*	rseg = trx->rsegs.m_redo.rseg;

	mtr.start();

	/* Change the undo log segment states from TRX_UNDO_ACTIVE to
	TRX_UNDO_PREPARED: these modifications to the file data
	structure define the transaction as prepared in the file-based
	world, at the serialization point of lsn. */

	mutex_enter(&rseg->mutex);

	if (insert) {
		ut_ad(insert->rseg == rseg);
		trx_undo_set_state_at_prepare(trx, insert, false, &mtr);
	}

	if (update) {
		ut_ad(update->rseg == rseg);
		trx_undo_set_state_at_prepare(trx, update, false, &mtr);
	}

	mutex_exit(&rseg->mutex);

	/* Make the XA PREPARE durable. */
	mtr.commit();
	ut_ad(mtr.commit_lsn() > 0);
	return(mtr.commit_lsn());
}

/****************************************************************//**
Prepares a transaction. */
static
void
trx_prepare(
/*========*/
	trx_t*	trx)	/*!< in/out: transaction */
{
	/* Only fresh user transactions can be prepared.
	Recovered transactions cannot. */
	ut_a(!trx->is_recovered);

	lsn_t	lsn = trx_prepare_low(trx);

	DBUG_EXECUTE_IF("ib_trx_crash_during_xa_prepare_step", DBUG_SUICIDE(););

	/*--------------------------------------*/
	ut_a(trx->state == TRX_STATE_ACTIVE);
	trx_sys_mutex_enter();
	trx->state = TRX_STATE_PREPARED;
	trx_sys->n_prepared_trx++;
	trx_sys_mutex_exit();
	/*--------------------------------------*/

	if (lsn) {
		/* Depending on the my.cnf options, we may now write the log
		buffer to the log files, making the prepared state of the
		transaction durable if the OS does not crash. We may also
		flush the log files to disk, making the prepared state of the
		transaction durable also at an OS crash or a power outage.

		The idea in InnoDB's group prepare is that a group of
		transactions gather behind a trx doing a physical disk write
		to log files, and when that physical write has been completed,
		one of those transactions does a write which prepares the whole
		group. Note that this group prepare will only bring benefit if
		there are > 2 users in the database. Then at least 2 users can
		gather behind one doing the physical log write to disk.

		We must not be holding any mutexes or latches here. */

		trx_flush_log_if_needed(lsn, trx);
	}
}

/** XA PREPARE a transaction.
@param[in,out]	trx	transaction to prepare */
void trx_prepare_for_mysql(trx_t* trx)
{
	trx_start_if_not_started_xa(trx, false);

	trx->op_info = "preparing";

	trx_prepare(trx);

	trx->op_info = "";
}

/**********************************************************************//**
This function is used to find number of prepared transactions and
their transaction objects for a recovery.
@return number of prepared transactions stored in xid_list */
int
trx_recover_for_mysql(
/*==================*/
	XID*	xid_list,	/*!< in/out: prepared transactions */
	ulint	len)		/*!< in: number of slots in xid_list */
{
	trx_t*		trx;
	ulint		count = 0;

	ut_ad(xid_list);
	ut_ad(len);

	/* We should set those transactions which are in the prepared state
	to the xid_list */

	trx_sys_mutex_enter();

	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);

		/* The state of a read-write transaction cannot change
		from or to NOT_STARTED while we are holding the
		trx_sys->mutex. It may change to PREPARED, but not if
		trx->is_recovered. It may also change to COMMITTED. */
		if (trx_state_eq(trx, TRX_STATE_PREPARED)) {
			trx->state = TRX_STATE_PREPARED_RECOVERED;
			xid_list[count] = *trx->xid;

			if (count == 0) {
				ib::info() << "Starting recovery for"
					" XA transactions...";
			}

			ib::info() << "Transaction "
				<< trx_get_id_for_print(trx)
				<< " in prepared state after recovery";

			ib::info() << "Transaction contains changes to "
				<< trx->undo_no << " rows";

			count++;

			if (count == len) {
				goto partial;
			}
		}
	}

	/* After returning the full list, reset the state, because
	there will be a second call to recover the transactions. */
	for (trx = UT_LIST_GET_FIRST(trx_sys->rw_trx_list);
	     trx != NULL;
	     trx = UT_LIST_GET_NEXT(trx_list, trx)) {
		if (trx_state_eq(trx, TRX_STATE_PREPARED_RECOVERED)) {
			trx->state = TRX_STATE_PREPARED;
		}
	}

partial:
	trx_sys_mutex_exit();

	if (count > 0){
		ib::info() << count << " transactions in prepared state"
			" after recovery";
	}

	return(int (count));
}

/*******************************************************************//**
This function is used to find one X/Open XA distributed transaction
which is in the prepared state
@return trx on match, the trx->xid will be invalidated;
note that the trx may have been committed, unless the caller is
holding lock_sys->mutex */
static MY_ATTRIBUTE((warn_unused_result))
trx_t*
trx_get_trx_by_xid_low(
/*===================*/
	XID*	xid)		/*!< in: X/Open XA transaction
					identifier */
{
	trx_t*		trx;

	ut_ad(trx_sys_mutex_own());

	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);

		/* Compare two X/Open XA transaction id's: their
		length should be the same and binary comparison
		of gtrid_length+bqual_length bytes should be
		the same */

		if (trx->is_recovered
		    && (trx_state_eq(trx, TRX_STATE_PREPARED)
			|| trx_state_eq(trx, TRX_STATE_PREPARED_RECOVERED))
		    && xid->eq(trx->xid)) {
#ifdef WITH_WSREP
			/* The commit of a prepared recovered Galera
			transaction needs a valid trx->xid for
			invoking trx_sys_update_wsrep_checkpoint(). */
			if (wsrep_is_wsrep_xid(trx->xid)) break;
#endif
			/* Invalidate the XID, so that subsequent calls
			will not find it. */
			trx->xid->null();
			break;
		}
	}

	return(trx);
}

/*******************************************************************//**
This function is used to find one X/Open XA distributed transaction
which is in the prepared state
@return trx or NULL; on match, the trx->xid will be invalidated;
note that the trx may have been committed, unless the caller is
holding lock_sys->mutex */
trx_t*
trx_get_trx_by_xid(
/*===============*/
	XID*	xid)	/*!< in: X/Open XA transaction identifier */
{
	trx_t*	trx;

	if (xid == NULL) {

		return(NULL);
	}

	trx_sys_mutex_enter();

	/* Recovered/Resurrected transactions are always only on the
	trx_sys_t::rw_trx_list. */
	trx = trx_get_trx_by_xid_low((XID*)xid);

	trx_sys_mutex_exit();

	return(trx);
}

/*************************************************************//**
Starts the transaction if it is not yet started. */
void
trx_start_if_not_started_xa_low(
/*============================*/
	trx_t*	trx,		/*!< in/out: transaction */
	bool	read_write)	/*!< in: true if read write transaction */
{
	switch (trx->state) {
	case TRX_STATE_NOT_STARTED:
		trx_start_low(trx, read_write);
		return;

	case TRX_STATE_ACTIVE:
		if (trx->id == 0 && read_write) {
			/* If the transaction is tagged as read-only then
			it can only write to temp tables and for such
			transactions we don't want to move them to the
			trx_sys_t::rw_trx_list. */
			if (!trx->read_only) {
				trx_set_rw_mode(trx);
			}
		}
		return;
	case TRX_STATE_PREPARED:
	case TRX_STATE_PREPARED_RECOVERED:
	case TRX_STATE_COMMITTED_IN_MEMORY:
		break;
	}

	ut_error;
}

/*************************************************************//**
Starts the transaction if it is not yet started. */
void
trx_start_if_not_started_low(
/*==========================*/
	trx_t*	trx,		/*!< in: transaction */
	bool	read_write)	/*!< in: true if read write transaction */
{
	switch (trx->state) {
	case TRX_STATE_NOT_STARTED:
		trx_start_low(trx, read_write);
		return;

	case TRX_STATE_ACTIVE:
		if (read_write && trx->id == 0 && !trx->read_only) {
			trx_set_rw_mode(trx);
		}
		return;

	case TRX_STATE_PREPARED:
	case TRX_STATE_PREPARED_RECOVERED:
	case TRX_STATE_COMMITTED_IN_MEMORY:
		break;
	}

	ut_error;
}

/*************************************************************//**
Starts a transaction for internal processing. */
void
trx_start_internal_low(
/*===================*/
	trx_t*	trx)		/*!< in/out: transaction */
{
	/* Ensure it is not flagged as an auto-commit-non-locking
	transaction. */

	trx->will_lock = 1;

	trx->internal = true;

	trx_start_low(trx, true);
}

/** Starts a read-only transaction for internal processing.
@param[in,out] trx	transaction to be started */
void
trx_start_internal_read_only_low(
	trx_t*	trx)
{
	/* Ensure it is not flagged as an auto-commit-non-locking
	transaction. */

	trx->will_lock = 1;

	trx->internal = true;

	trx_start_low(trx, false);
}

/*************************************************************//**
Starts the transaction for a DDL operation. */
void
trx_start_for_ddl_low(
/*==================*/
	trx_t*		trx,	/*!< in/out: transaction */
	trx_dict_op_t	op)	/*!< in: dictionary operation type */
{
	switch (trx->state) {
	case TRX_STATE_NOT_STARTED:
		/* Flag this transaction as a dictionary operation, so that
		the data dictionary will be locked in crash recovery. */

		trx_set_dict_operation(trx, op);

		/* Ensure it is not flagged as an auto-commit-non-locking
		transation. */
		trx->will_lock = 1;

		trx->ddl= true;

		trx_start_internal_low(trx);
		return;

	case TRX_STATE_ACTIVE:

		/* We have this start if not started idiom, therefore we
		can't add stronger checks here. */
		trx->ddl = true;

		ut_ad(trx->dict_operation != TRX_DICT_OP_NONE);
		ut_ad(trx->will_lock > 0);
		return;

	case TRX_STATE_PREPARED:
	case TRX_STATE_PREPARED_RECOVERED:
	case TRX_STATE_COMMITTED_IN_MEMORY:
		break;
	}

	ut_error;
}

/*************************************************************//**
Set the transaction as a read-write transaction if it is not already
tagged as such. Read-only transactions that are writing to temporary
tables are assigned an ID and a rollback segment but are not added
to the trx read-write list because their updates should not be visible
to other transactions and therefore their changes can be ignored by
by MVCC. */
void
trx_set_rw_mode(
/*============*/
	trx_t*		trx)		/*!< in/out: transaction that is RW */
{
	ut_ad(trx->rsegs.m_redo.rseg == 0);
	ut_ad(!trx->in_rw_trx_list);
	ut_ad(!trx_is_autocommit_non_locking(trx));
	ut_ad(!trx->read_only);

	if (high_level_read_only) {
		return;
	}

	/* Function is promoting existing trx from ro mode to rw mode.
	In this process it has acquired trx_sys->mutex as it plan to
	move trx from ro list to rw list. If in future, some other thread
	looks at this trx object while it is being promoted then ensure
	that both threads are synced by acquring trx->mutex to avoid decision
	based on in-consistent view formed during promotion. */

	trx->rsegs.m_redo.rseg = trx_assign_rseg_low();

	ut_ad(trx->rsegs.m_redo.rseg != 0);

	mutex_enter(&trx_sys->mutex);

	ut_ad(trx->id == 0);
	trx->id = trx_sys_get_new_trx_id();

	trx_sys->rw_trx_ids.push_back(trx->id);

	trx_sys->rw_trx_set.insert(TrxTrack(trx->id, trx));

	/* So that we can see our own changes. */
	if (MVCC::is_view_active(trx->read_view)) {
		MVCC::set_view_creator_trx_id(trx->read_view, trx->id);
	}

#ifdef UNIV_DEBUG
	if (trx->id > trx_sys->rw_max_trx_id) {
		trx_sys->rw_max_trx_id = trx->id;
	}
#endif /* UNIV_DEBUG */

	UT_LIST_ADD_FIRST(trx_sys->rw_trx_list, trx);

	ut_d(trx->in_rw_trx_list = true);

	mutex_exit(&trx_sys->mutex);
}