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|
/*****************************************************************************
Copyright (c) 1996, 2010, Innobase Oy. 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., 59 Temple
Place, Suite 330, Boston, MA 02111-1307 USA
*****************************************************************************/
/**************************************************//**
@file lock/lock0lock.c
The transaction lock system
Created 5/7/1996 Heikki Tuuri
*******************************************************/
#define LOCK_MODULE_IMPLEMENTATION
#include "lock0lock.h"
#include "lock0priv.h"
#ifdef UNIV_NONINL
#include "lock0lock.ic"
#include "lock0priv.ic"
#endif
#include "ha_prototypes.h"
#include "usr0sess.h"
#include "trx0purge.h"
#include "dict0mem.h"
#include "trx0sys.h"
/* Restricts the length of search we will do in the waits-for
graph of transactions */
#define LOCK_MAX_N_STEPS_IN_DEADLOCK_CHECK 1000000
/* Restricts the recursion depth of the search we will do in the waits-for
graph of transactions */
#define LOCK_MAX_DEPTH_IN_DEADLOCK_CHECK 200
/* When releasing transaction locks, this specifies how often we release
the kernel mutex for a moment to give also others access to it */
#define LOCK_RELEASE_KERNEL_INTERVAL 1000
/* Safety margin when creating a new record lock: this many extra records
can be inserted to the page without need to create a lock with a bigger
bitmap */
#define LOCK_PAGE_BITMAP_MARGIN 64
/* An explicit record lock affects both the record and the gap before it.
An implicit x-lock does not affect the gap, it only locks the index
record from read or update.
If a transaction has modified or inserted an index record, then
it owns an implicit x-lock on the record. On a secondary index record,
a transaction has an implicit x-lock also if it has modified the
clustered index record, the max trx id of the page where the secondary
index record resides is >= trx id of the transaction (or database recovery
is running), and there are no explicit non-gap lock requests on the
secondary index record.
This complicated definition for a secondary index comes from the
implementation: we want to be able to determine if a secondary index
record has an implicit x-lock, just by looking at the present clustered
index record, not at the historical versions of the record. The
complicated definition can be explained to the user so that there is
nondeterminism in the access path when a query is answered: we may,
or may not, access the clustered index record and thus may, or may not,
bump into an x-lock set there.
Different transaction can have conflicting locks set on the gap at the
same time. The locks on the gap are purely inhibitive: an insert cannot
be made, or a select cursor may have to wait if a different transaction
has a conflicting lock on the gap. An x-lock on the gap does not give
the right to insert into the gap.
An explicit lock can be placed on a user record or the supremum record of
a page. The locks on the supremum record are always thought to be of the gap
type, though the gap bit is not set. When we perform an update of a record
where the size of the record changes, we may temporarily store its explicit
locks on the infimum record of the page, though the infimum otherwise never
carries locks.
A waiting record lock can also be of the gap type. A waiting lock request
can be granted when there is no conflicting mode lock request by another
transaction ahead of it in the explicit lock queue.
In version 4.0.5 we added yet another explicit lock type: LOCK_REC_NOT_GAP.
It only locks the record it is placed on, not the gap before the record.
This lock type is necessary to emulate an Oracle-like READ COMMITTED isolation
level.
-------------------------------------------------------------------------
RULE 1: If there is an implicit x-lock on a record, and there are non-gap
-------
lock requests waiting in the queue, then the transaction holding the implicit
x-lock also has an explicit non-gap record x-lock. Therefore, as locks are
released, we can grant locks to waiting lock requests purely by looking at
the explicit lock requests in the queue.
RULE 3: Different transactions cannot have conflicting granted non-gap locks
-------
on a record at the same time. However, they can have conflicting granted gap
locks.
RULE 4: If a there is a waiting lock request in a queue, no lock request,
-------
gap or not, can be inserted ahead of it in the queue. In record deletes
and page splits new gap type locks can be created by the database manager
for a transaction, and without rule 4, the waits-for graph of transactions
might become cyclic without the database noticing it, as the deadlock check
is only performed when a transaction itself requests a lock!
-------------------------------------------------------------------------
An insert is allowed to a gap if there are no explicit lock requests by
other transactions on the next record. It does not matter if these lock
requests are granted or waiting, gap bit set or not, with the exception
that a gap type request set by another transaction to wait for
its turn to do an insert is ignored. On the other hand, an
implicit x-lock by another transaction does not prevent an insert, which
allows for more concurrency when using an Oracle-style sequence number
generator for the primary key with many transactions doing inserts
concurrently.
A modify of a record is allowed if the transaction has an x-lock on the
record, or if other transactions do not have any non-gap lock requests on the
record.
A read of a single user record with a cursor is allowed if the transaction
has a non-gap explicit, or an implicit lock on the record, or if the other
transactions have no x-lock requests on the record. At a page supremum a
read is always allowed.
In summary, an implicit lock is seen as a granted x-lock only on the
record, not on the gap. An explicit lock with no gap bit set is a lock
both on the record and the gap. If the gap bit is set, the lock is only
on the gap. Different transaction cannot own conflicting locks on the
record at the same time, but they may own conflicting locks on the gap.
Granted locks on a record give an access right to the record, but gap type
locks just inhibit operations.
NOTE: Finding out if some transaction has an implicit x-lock on a secondary
index record can be cumbersome. We may have to look at previous versions of
the corresponding clustered index record to find out if a delete marked
secondary index record was delete marked by an active transaction, not by
a committed one.
FACT A: If a transaction has inserted a row, it can delete it any time
without need to wait for locks.
PROOF: The transaction has an implicit x-lock on every index record inserted
for the row, and can thus modify each record without the need to wait. Q.E.D.
FACT B: If a transaction has read some result set with a cursor, it can read
it again, and retrieves the same result set, if it has not modified the
result set in the meantime. Hence, there is no phantom problem. If the
biggest record, in the alphabetical order, touched by the cursor is removed,
a lock wait may occur, otherwise not.
PROOF: When a read cursor proceeds, it sets an s-lock on each user record
it passes, and a gap type s-lock on each page supremum. The cursor must
wait until it has these locks granted. Then no other transaction can
have a granted x-lock on any of the user records, and therefore cannot
modify the user records. Neither can any other transaction insert into
the gaps which were passed over by the cursor. Page splits and merges,
and removal of obsolete versions of records do not affect this, because
when a user record or a page supremum is removed, the next record inherits
its locks as gap type locks, and therefore blocks inserts to the same gap.
Also, if a page supremum is inserted, it inherits its locks from the successor
record. When the cursor is positioned again at the start of the result set,
the records it will touch on its course are either records it touched
during the last pass or new inserted page supremums. It can immediately
access all these records, and when it arrives at the biggest record, it
notices that the result set is complete. If the biggest record was removed,
lock wait can occur because the next record only inherits a gap type lock,
and a wait may be needed. Q.E.D. */
/* If an index record should be changed or a new inserted, we must check
the lock on the record or the next. When a read cursor starts reading,
we will set a record level s-lock on each record it passes, except on the
initial record on which the cursor is positioned before we start to fetch
records. Our index tree search has the convention that the B-tree
cursor is positioned BEFORE the first possibly matching record in
the search. Optimizations are possible here: if the record is searched
on an equality condition to a unique key, we could actually set a special
lock on the record, a lock which would not prevent any insert before
this record. In the next key locking an x-lock set on a record also
prevents inserts just before that record.
There are special infimum and supremum records on each page.
A supremum record can be locked by a read cursor. This records cannot be
updated but the lock prevents insert of a user record to the end of
the page.
Next key locks will prevent the phantom problem where new rows
could appear to SELECT result sets after the select operation has been
performed. Prevention of phantoms ensures the serilizability of
transactions.
What should we check if an insert of a new record is wanted?
Only the lock on the next record on the same page, because also the
supremum record can carry a lock. An s-lock prevents insertion, but
what about an x-lock? If it was set by a searched update, then there
is implicitly an s-lock, too, and the insert should be prevented.
What if our transaction owns an x-lock to the next record, but there is
a waiting s-lock request on the next record? If this s-lock was placed
by a read cursor moving in the ascending order in the index, we cannot
do the insert immediately, because when we finally commit our transaction,
the read cursor should see also the new inserted record. So we should
move the read cursor backward from the next record for it to pass over
the new inserted record. This move backward may be too cumbersome to
implement. If we in this situation just enqueue a second x-lock request
for our transaction on the next record, then the deadlock mechanism
notices a deadlock between our transaction and the s-lock request
transaction. This seems to be an ok solution.
We could have the convention that granted explicit record locks,
lock the corresponding records from changing, and also lock the gaps
before them from inserting. A waiting explicit lock request locks the gap
before from inserting. Implicit record x-locks, which we derive from the
transaction id in the clustered index record, only lock the record itself
from modification, not the gap before it from inserting.
How should we store update locks? If the search is done by a unique
key, we could just modify the record trx id. Otherwise, we could put a record
x-lock on the record. If the update changes ordering fields of the
clustered index record, the inserted new record needs no record lock in
lock table, the trx id is enough. The same holds for a secondary index
record. Searched delete is similar to update.
PROBLEM:
What about waiting lock requests? If a transaction is waiting to make an
update to a record which another modified, how does the other transaction
know to send the end-lock-wait signal to the waiting transaction? If we have
the convention that a transaction may wait for just one lock at a time, how
do we preserve it if lock wait ends?
PROBLEM:
Checking the trx id label of a secondary index record. In the case of a
modification, not an insert, is this necessary? A secondary index record
is modified only by setting or resetting its deleted flag. A secondary index
record contains fields to uniquely determine the corresponding clustered
index record. A secondary index record is therefore only modified if we
also modify the clustered index record, and the trx id checking is done
on the clustered index record, before we come to modify the secondary index
record. So, in the case of delete marking or unmarking a secondary index
record, we do not have to care about trx ids, only the locks in the lock
table must be checked. In the case of a select from a secondary index, the
trx id is relevant, and in this case we may have to search the clustered
index record.
PROBLEM: How to update record locks when page is split or merged, or
--------------------------------------------------------------------
a record is deleted or updated?
If the size of fields in a record changes, we perform the update by
a delete followed by an insert. How can we retain the locks set or
waiting on the record? Because a record lock is indexed in the bitmap
by the heap number of the record, when we remove the record from the
record list, it is possible still to keep the lock bits. If the page
is reorganized, we could make a table of old and new heap numbers,
and permute the bitmaps in the locks accordingly. We can add to the
table a row telling where the updated record ended. If the update does
not require a reorganization of the page, we can simply move the lock
bits for the updated record to the position determined by its new heap
number (we may have to allocate a new lock, if we run out of the bitmap
in the old one).
A more complicated case is the one where the reinsertion of the
updated record is done pessimistically, because the structure of the
tree may change.
PROBLEM: If a supremum record is removed in a page merge, or a record
---------------------------------------------------------------------
removed in a purge, what to do to the waiting lock requests? In a split to
the right, we just move the lock requests to the new supremum. If a record
is removed, we could move the waiting lock request to its inheritor, the
next record in the index. But, the next record may already have lock
requests on its own queue. A new deadlock check should be made then. Maybe
it is easier just to release the waiting transactions. They can then enqueue
new lock requests on appropriate records.
PROBLEM: When a record is inserted, what locks should it inherit from the
-------------------------------------------------------------------------
upper neighbor? An insert of a new supremum record in a page split is
always possible, but an insert of a new user record requires that the upper
neighbor does not have any lock requests by other transactions, granted or
waiting, in its lock queue. Solution: We can copy the locks as gap type
locks, so that also the waiting locks are transformed to granted gap type
locks on the inserted record. */
/* LOCK COMPATIBILITY MATRIX
* IS IX S X AI
* IS + + + - +
* IX + + - - +
* S + - + - -
* X - - - - -
* AI + + - - -
*
* Note that for rows, InnoDB only acquires S or X locks.
* For tables, InnoDB normally acquires IS or IX locks.
* S or X table locks are only acquired for LOCK TABLES.
* Auto-increment (AI) locks are needed because of
* statement-level MySQL binlog.
* See also lock_mode_compatible().
*/
#define LK(a,b) (1 << ((a) * LOCK_NUM + (b)))
#define LKS(a,b) LK(a,b) | LK(b,a)
/* Define the lock compatibility matrix in a ulint. The first line below
defines the diagonal entries. The following lines define the compatibility
for LOCK_IX, LOCK_S, and LOCK_AUTO_INC using LKS(), since the matrix
is symmetric. */
#define LOCK_MODE_COMPATIBILITY 0 \
| LK(LOCK_IS, LOCK_IS) | LK(LOCK_IX, LOCK_IX) | LK(LOCK_S, LOCK_S) \
| LKS(LOCK_IX, LOCK_IS) | LKS(LOCK_IS, LOCK_AUTO_INC) \
| LKS(LOCK_S, LOCK_IS) \
| LKS(LOCK_AUTO_INC, LOCK_IS) | LKS(LOCK_AUTO_INC, LOCK_IX)
/* STRONGER-OR-EQUAL RELATION (mode1=row, mode2=column)
* IS IX S X AI
* IS + - - - -
* IX + + - - -
* S + - + - -
* X + + + + +
* AI - - - - +
* See lock_mode_stronger_or_eq().
*/
/* Define the stronger-or-equal lock relation in a ulint. This relation
contains all pairs LK(mode1, mode2) where mode1 is stronger than or
equal to mode2. */
#define LOCK_MODE_STRONGER_OR_EQ 0 \
| LK(LOCK_IS, LOCK_IS) \
| LK(LOCK_IX, LOCK_IS) | LK(LOCK_IX, LOCK_IX) \
| LK(LOCK_S, LOCK_IS) | LK(LOCK_S, LOCK_S) \
| LK(LOCK_AUTO_INC, LOCK_AUTO_INC) \
| LK(LOCK_X, LOCK_IS) | LK(LOCK_X, LOCK_IX) | LK(LOCK_X, LOCK_S) \
| LK(LOCK_X, LOCK_AUTO_INC) | LK(LOCK_X, LOCK_X)
#ifdef UNIV_DEBUG
UNIV_INTERN ibool lock_print_waits = FALSE;
/*********************************************************************//**
Validates the lock system.
@return TRUE if ok */
static
ibool
lock_validate(void);
/*===============*/
/*********************************************************************//**
Validates the record lock queues on a page.
@return TRUE if ok */
static
ibool
lock_rec_validate_page(
/*===================*/
ulint space, /*!< in: space id */
ulint zip_size,/*!< in: compressed page size in bytes
or 0 for uncompressed pages */
ulint page_no);/*!< in: page number */
#endif /* UNIV_DEBUG */
/* The lock system */
UNIV_INTERN lock_sys_t* lock_sys = NULL;
/* We store info on the latest deadlock error to this buffer. InnoDB
Monitor will then fetch it and print */
UNIV_INTERN ibool lock_deadlock_found = FALSE;
UNIV_INTERN FILE* lock_latest_err_file;
/* Flags for recursive deadlock search */
#define LOCK_VICTIM_IS_START 1
#define LOCK_VICTIM_IS_OTHER 2
#define LOCK_EXCEED_MAX_DEPTH 3
/********************************************************************//**
Checks if a lock request results in a deadlock.
@return TRUE if a deadlock was detected and we chose trx as a victim;
FALSE if no deadlock, or there was a deadlock, but we chose other
transaction(s) as victim(s) */
static
ibool
lock_deadlock_occurs(
/*=================*/
lock_t* lock, /*!< in: lock the transaction is requesting */
trx_t* trx); /*!< in: transaction */
/********************************************************************//**
Looks recursively for a deadlock.
@return 0 if no deadlock found, LOCK_VICTIM_IS_START if there was a
deadlock and we chose 'start' as the victim, LOCK_VICTIM_IS_OTHER if a
deadlock was found and we chose some other trx as a victim: we must do
the search again in this last case because there may be another
deadlock!
LOCK_EXCEED_MAX_DEPTH if the lock search exceeds max steps or max depth. */
static
ulint
lock_deadlock_recursive(
/*====================*/
trx_t* start, /*!< in: recursion starting point */
trx_t* trx, /*!< in: a transaction waiting for a lock */
lock_t* wait_lock, /*!< in: lock that is waiting to be granted */
ulint* cost, /*!< in/out: number of calculation steps thus
far: if this exceeds LOCK_MAX_N_STEPS_...
we return LOCK_EXCEED_MAX_DEPTH */
ulint depth); /*!< in: recursion depth: if this exceeds
LOCK_MAX_DEPTH_IN_DEADLOCK_CHECK, we
return LOCK_EXCEED_MAX_DEPTH */
/*********************************************************************//**
Gets the nth bit of a record lock.
@return TRUE if bit set also if i == ULINT_UNDEFINED return FALSE*/
UNIV_INLINE
ibool
lock_rec_get_nth_bit(
/*=================*/
const lock_t* lock, /*!< in: record lock */
ulint i) /*!< in: index of the bit */
{
ulint byte_index;
ulint bit_index;
ut_ad(lock);
ut_ad(lock_get_type_low(lock) == LOCK_REC);
if (i >= lock->un_member.rec_lock.n_bits) {
return(FALSE);
}
byte_index = i / 8;
bit_index = i % 8;
return(1 & ((const byte*) &lock[1])[byte_index] >> bit_index);
}
/*************************************************************************/
#define lock_mutex_enter_kernel() mutex_enter(&kernel_mutex)
#define lock_mutex_exit_kernel() mutex_exit(&kernel_mutex)
/*********************************************************************//**
Checks that a transaction id is sensible, i.e., not in the future.
@return TRUE if ok */
UNIV_INTERN
ibool
lock_check_trx_id_sanity(
/*=====================*/
trx_id_t trx_id, /*!< in: trx id */
const rec_t* rec, /*!< in: user record */
dict_index_t* index, /*!< in: index */
const ulint* offsets, /*!< in: rec_get_offsets(rec, index) */
ibool has_kernel_mutex)/*!< in: TRUE if the caller owns the
kernel mutex */
{
ibool is_ok = TRUE;
ut_ad(rec_offs_validate(rec, index, offsets));
if (!has_kernel_mutex) {
mutex_enter(&kernel_mutex);
}
/* A sanity check: the trx_id in rec must be smaller than the global
trx id counter */
if (ut_dulint_cmp(trx_id, trx_sys->max_trx_id) >= 0) {
ut_print_timestamp(stderr);
fputs(" InnoDB: Error: transaction id associated"
" with record\n",
stderr);
rec_print_new(stderr, rec, offsets);
fputs("InnoDB: in ", stderr);
dict_index_name_print(stderr, NULL, index);
fprintf(stderr, "\n"
"InnoDB: is " TRX_ID_FMT " which is higher than the"
" global trx id counter " TRX_ID_FMT "!\n"
"InnoDB: The table is corrupt. You have to do"
" dump + drop + reimport.\n",
TRX_ID_PREP_PRINTF(trx_id),
TRX_ID_PREP_PRINTF(trx_sys->max_trx_id));
is_ok = FALSE;
}
if (!has_kernel_mutex) {
mutex_exit(&kernel_mutex);
}
return(is_ok);
}
/*********************************************************************//**
Checks that a record is seen in a consistent read.
@return TRUE if sees, or FALSE if an earlier version of the record
should be retrieved */
UNIV_INTERN
ibool
lock_clust_rec_cons_read_sees(
/*==========================*/
const rec_t* rec, /*!< in: user record which should be read or
passed over by a read cursor */
dict_index_t* index, /*!< in: clustered index */
const ulint* offsets,/*!< in: rec_get_offsets(rec, index) */
read_view_t* view) /*!< in: consistent read view */
{
trx_id_t trx_id;
ut_ad(dict_index_is_clust(index));
ut_ad(page_rec_is_user_rec(rec));
ut_ad(rec_offs_validate(rec, index, offsets));
/* NOTE that we call this function while holding the search
system latch. To obey the latching order we must NOT reserve the
kernel mutex here! */
trx_id = row_get_rec_trx_id(rec, index, offsets);
return(read_view_sees_trx_id(view, trx_id));
}
/*********************************************************************//**
Checks that a non-clustered index record is seen in a consistent read.
NOTE that a non-clustered index page contains so little information on
its modifications that also in the case FALSE, the present version of
rec may be the right, but we must check this from the clustered index
record.
@return TRUE if certainly sees, or FALSE if an earlier version of the
clustered index record might be needed */
UNIV_INTERN
ulint
lock_sec_rec_cons_read_sees(
/*========================*/
const rec_t* rec, /*!< in: user record which
should be read or passed over
by a read cursor */
const read_view_t* view) /*!< in: consistent read view */
{
trx_id_t max_trx_id;
ut_ad(page_rec_is_user_rec(rec));
/* NOTE that we might call this function while holding the search
system latch. To obey the latching order we must NOT reserve the
kernel mutex here! */
if (recv_recovery_is_on()) {
return(FALSE);
}
max_trx_id = page_get_max_trx_id(page_align(rec));
ut_ad(!ut_dulint_is_zero(max_trx_id));
return(ut_dulint_cmp(max_trx_id, view->up_limit_id) < 0);
}
/*********************************************************************//**
Creates the lock system at database start. */
UNIV_INTERN
void
lock_sys_create(
/*============*/
ulint n_cells) /*!< in: number of slots in lock hash table */
{
lock_sys = mem_alloc(sizeof(lock_sys_t));
lock_sys->rec_hash = hash_create(n_cells);
/* hash_create_mutexes(lock_sys->rec_hash, 2, SYNC_REC_LOCK); */
lock_latest_err_file = os_file_create_tmpfile();
ut_a(lock_latest_err_file);
}
/*********************************************************************//**
Closes the lock system at database shutdown. */
UNIV_INTERN
void
lock_sys_close(void)
/*================*/
{
if (lock_latest_err_file != NULL) {
fclose(lock_latest_err_file);
lock_latest_err_file = NULL;
}
hash_table_free(lock_sys->rec_hash);
mem_free(lock_sys);
lock_sys = NULL;
}
/*********************************************************************//**
Gets the size of a lock struct.
@return size in bytes */
UNIV_INTERN
ulint
lock_get_size(void)
/*===============*/
{
return((ulint)sizeof(lock_t));
}
/*********************************************************************//**
Gets the mode of a lock.
@return mode */
UNIV_INLINE
enum lock_mode
lock_get_mode(
/*==========*/
const lock_t* lock) /*!< in: lock */
{
ut_ad(lock);
return(lock->type_mode & LOCK_MODE_MASK);
}
/*********************************************************************//**
Gets the wait flag of a lock.
@return TRUE if waiting */
UNIV_INLINE
ibool
lock_get_wait(
/*==========*/
const lock_t* lock) /*!< in: lock */
{
ut_ad(lock);
if (UNIV_UNLIKELY(lock->type_mode & LOCK_WAIT)) {
return(TRUE);
}
return(FALSE);
}
/*********************************************************************//**
Gets the source table of an ALTER TABLE transaction. The table must be
covered by an IX or IS table lock.
@return the source table of transaction, if it is covered by an IX or
IS table lock; dest if there is no source table, and NULL if the
transaction is locking more than two tables or an inconsistency is
found */
UNIV_INTERN
dict_table_t*
lock_get_src_table(
/*===============*/
trx_t* trx, /*!< in: transaction */
dict_table_t* dest, /*!< in: destination of ALTER TABLE */
enum lock_mode* mode) /*!< out: lock mode of the source table */
{
dict_table_t* src;
lock_t* lock;
src = NULL;
*mode = LOCK_NONE;
for (lock = UT_LIST_GET_FIRST(trx->trx_locks);
lock;
lock = UT_LIST_GET_NEXT(trx_locks, lock)) {
lock_table_t* tab_lock;
enum lock_mode lock_mode;
if (!(lock_get_type_low(lock) & LOCK_TABLE)) {
/* We are only interested in table locks. */
continue;
}
tab_lock = &lock->un_member.tab_lock;
if (dest == tab_lock->table) {
/* We are not interested in the destination table. */
continue;
} else if (!src) {
/* This presumably is the source table. */
src = tab_lock->table;
if (UT_LIST_GET_LEN(src->locks) != 1
|| UT_LIST_GET_FIRST(src->locks) != lock) {
/* We only support the case when
there is only one lock on this table. */
return(NULL);
}
} else if (src != tab_lock->table) {
/* The transaction is locking more than
two tables (src and dest): abort */
return(NULL);
}
/* Check that the source table is locked by
LOCK_IX or LOCK_IS. */
lock_mode = lock_get_mode(lock);
if (lock_mode == LOCK_IX || lock_mode == LOCK_IS) {
if (*mode != LOCK_NONE && *mode != lock_mode) {
/* There are multiple locks on src. */
return(NULL);
}
*mode = lock_mode;
}
}
if (!src) {
/* No source table lock found: flag the situation to caller */
src = dest;
}
return(src);
}
/*********************************************************************//**
Determine if the given table is exclusively "owned" by the given
transaction, i.e., transaction holds LOCK_IX and possibly LOCK_AUTO_INC
on the table.
@return TRUE if table is only locked by trx, with LOCK_IX, and
possibly LOCK_AUTO_INC */
UNIV_INTERN
ibool
lock_is_table_exclusive(
/*====================*/
dict_table_t* table, /*!< in: table */
trx_t* trx) /*!< in: transaction */
{
const lock_t* lock;
ibool ok = FALSE;
ut_ad(table);
ut_ad(trx);
lock_mutex_enter_kernel();
for (lock = UT_LIST_GET_FIRST(table->locks);
lock;
lock = UT_LIST_GET_NEXT(locks, &lock->un_member.tab_lock)) {
if (lock->trx != trx) {
/* A lock on the table is held
by some other transaction. */
goto not_ok;
}
if (!(lock_get_type_low(lock) & LOCK_TABLE)) {
/* We are interested in table locks only. */
continue;
}
switch (lock_get_mode(lock)) {
case LOCK_IX:
ok = TRUE;
break;
case LOCK_AUTO_INC:
/* It is allowed for trx to hold an
auto_increment lock. */
break;
default:
not_ok:
/* Other table locks than LOCK_IX are not allowed. */
ok = FALSE;
goto func_exit;
}
}
func_exit:
lock_mutex_exit_kernel();
return(ok);
}
/*********************************************************************//**
Sets the wait flag of a lock and the back pointer in trx to lock. */
UNIV_INLINE
void
lock_set_lock_and_trx_wait(
/*=======================*/
lock_t* lock, /*!< in: lock */
trx_t* trx) /*!< in: trx */
{
ut_ad(lock);
ut_ad(trx->wait_lock == NULL);
trx->wait_lock = lock;
lock->type_mode |= LOCK_WAIT;
}
/**********************************************************************//**
The back pointer to a waiting lock request in the transaction is set to NULL
and the wait bit in lock type_mode is reset. */
UNIV_INLINE
void
lock_reset_lock_and_trx_wait(
/*=========================*/
lock_t* lock) /*!< in: record lock */
{
ut_ad((lock->trx)->wait_lock == lock);
ut_ad(lock_get_wait(lock));
/* Reset the back pointer in trx to this waiting lock request */
(lock->trx)->wait_lock = NULL;
lock->type_mode &= ~LOCK_WAIT;
}
/*********************************************************************//**
Gets the gap flag of a record lock.
@return TRUE if gap flag set */
UNIV_INLINE
ibool
lock_rec_get_gap(
/*=============*/
const lock_t* lock) /*!< in: record lock */
{
ut_ad(lock);
ut_ad(lock_get_type_low(lock) == LOCK_REC);
if (lock->type_mode & LOCK_GAP) {
return(TRUE);
}
return(FALSE);
}
/*********************************************************************//**
Gets the LOCK_REC_NOT_GAP flag of a record lock.
@return TRUE if LOCK_REC_NOT_GAP flag set */
UNIV_INLINE
ibool
lock_rec_get_rec_not_gap(
/*=====================*/
const lock_t* lock) /*!< in: record lock */
{
ut_ad(lock);
ut_ad(lock_get_type_low(lock) == LOCK_REC);
if (lock->type_mode & LOCK_REC_NOT_GAP) {
return(TRUE);
}
return(FALSE);
}
/*********************************************************************//**
Gets the waiting insert flag of a record lock.
@return TRUE if gap flag set */
UNIV_INLINE
ibool
lock_rec_get_insert_intention(
/*==========================*/
const lock_t* lock) /*!< in: record lock */
{
ut_ad(lock);
ut_ad(lock_get_type_low(lock) == LOCK_REC);
if (lock->type_mode & LOCK_INSERT_INTENTION) {
return(TRUE);
}
return(FALSE);
}
/*********************************************************************//**
Calculates if lock mode 1 is stronger or equal to lock mode 2.
@return nonzero if mode1 stronger or equal to mode2 */
UNIV_INLINE
ulint
lock_mode_stronger_or_eq(
/*=====================*/
enum lock_mode mode1, /*!< in: lock mode */
enum lock_mode mode2) /*!< in: lock mode */
{
ut_ad(mode1 == LOCK_X || mode1 == LOCK_S || mode1 == LOCK_IX
|| mode1 == LOCK_IS || mode1 == LOCK_AUTO_INC);
ut_ad(mode2 == LOCK_X || mode2 == LOCK_S || mode2 == LOCK_IX
|| mode2 == LOCK_IS || mode2 == LOCK_AUTO_INC);
return((LOCK_MODE_STRONGER_OR_EQ) & LK(mode1, mode2));
}
/*********************************************************************//**
Calculates if lock mode 1 is compatible with lock mode 2.
@return nonzero if mode1 compatible with mode2 */
UNIV_INLINE
ulint
lock_mode_compatible(
/*=================*/
enum lock_mode mode1, /*!< in: lock mode */
enum lock_mode mode2) /*!< in: lock mode */
{
ut_ad(mode1 == LOCK_X || mode1 == LOCK_S || mode1 == LOCK_IX
|| mode1 == LOCK_IS || mode1 == LOCK_AUTO_INC);
ut_ad(mode2 == LOCK_X || mode2 == LOCK_S || mode2 == LOCK_IX
|| mode2 == LOCK_IS || mode2 == LOCK_AUTO_INC);
return((LOCK_MODE_COMPATIBILITY) & LK(mode1, mode2));
}
/*********************************************************************//**
Checks if a lock request for a new lock has to wait for request lock2.
@return TRUE if new lock has to wait for lock2 to be removed */
UNIV_INLINE
ibool
lock_rec_has_to_wait(
/*=================*/
const trx_t* trx, /*!< in: trx of new lock */
ulint type_mode,/*!< in: precise mode of the new lock
to set: LOCK_S or LOCK_X, possibly
ORed to LOCK_GAP or LOCK_REC_NOT_GAP,
LOCK_INSERT_INTENTION */
const lock_t* lock2, /*!< in: another record lock; NOTE that
it is assumed that this has a lock bit
set on the same record as in the new
lock we are setting */
ibool lock_is_on_supremum) /*!< in: TRUE if we are setting the
lock on the 'supremum' record of an
index page: we know then that the lock
request is really for a 'gap' type lock */
{
ut_ad(trx && lock2);
ut_ad(lock_get_type_low(lock2) == LOCK_REC);
if (trx != lock2->trx
&& !lock_mode_compatible(LOCK_MODE_MASK & type_mode,
lock_get_mode(lock2))) {
/* We have somewhat complex rules when gap type record locks
cause waits */
if ((lock_is_on_supremum || (type_mode & LOCK_GAP))
&& !(type_mode & LOCK_INSERT_INTENTION)) {
/* Gap type locks without LOCK_INSERT_INTENTION flag
do not need to wait for anything. This is because
different users can have conflicting lock types
on gaps. */
return(FALSE);
}
if (!(type_mode & LOCK_INSERT_INTENTION)
&& lock_rec_get_gap(lock2)) {
/* Record lock (LOCK_ORDINARY or LOCK_REC_NOT_GAP
does not need to wait for a gap type lock */
return(FALSE);
}
if ((type_mode & LOCK_GAP)
&& lock_rec_get_rec_not_gap(lock2)) {
/* Lock on gap does not need to wait for
a LOCK_REC_NOT_GAP type lock */
return(FALSE);
}
if (lock_rec_get_insert_intention(lock2)) {
/* No lock request needs to wait for an insert
intention lock to be removed. This is ok since our
rules allow conflicting locks on gaps. This eliminates
a spurious deadlock caused by a next-key lock waiting
for an insert intention lock; when the insert
intention lock was granted, the insert deadlocked on
the waiting next-key lock.
Also, insert intention locks do not disturb each
other. */
return(FALSE);
}
return(TRUE);
}
return(FALSE);
}
/*********************************************************************//**
Checks if a lock request lock1 has to wait for request lock2.
@return TRUE if lock1 has to wait for lock2 to be removed */
UNIV_INTERN
ibool
lock_has_to_wait(
/*=============*/
const lock_t* lock1, /*!< in: waiting lock */
const lock_t* lock2) /*!< in: another lock; NOTE that it is
assumed that this has a lock bit set
on the same record as in lock1 if the
locks are record locks */
{
ut_ad(lock1 && lock2);
if (lock1->trx != lock2->trx
&& !lock_mode_compatible(lock_get_mode(lock1),
lock_get_mode(lock2))) {
if (lock_get_type_low(lock1) == LOCK_REC) {
ut_ad(lock_get_type_low(lock2) == LOCK_REC);
/* If this lock request is for a supremum record
then the second bit on the lock bitmap is set */
return(lock_rec_has_to_wait(lock1->trx,
lock1->type_mode, lock2,
lock_rec_get_nth_bit(
lock1, 1)));
}
return(TRUE);
}
return(FALSE);
}
/*============== RECORD LOCK BASIC FUNCTIONS ============================*/
/*********************************************************************//**
Gets the number of bits in a record lock bitmap.
@return number of bits */
UNIV_INLINE
ulint
lock_rec_get_n_bits(
/*================*/
const lock_t* lock) /*!< in: record lock */
{
return(lock->un_member.rec_lock.n_bits);
}
/**********************************************************************//**
Sets the nth bit of a record lock to TRUE. */
UNIV_INLINE
void
lock_rec_set_nth_bit(
/*=================*/
lock_t* lock, /*!< in: record lock */
ulint i) /*!< in: index of the bit */
{
ulint byte_index;
ulint bit_index;
ut_ad(lock);
ut_ad(lock_get_type_low(lock) == LOCK_REC);
ut_ad(i < lock->un_member.rec_lock.n_bits);
byte_index = i / 8;
bit_index = i % 8;
((byte*) &lock[1])[byte_index] |= 1 << bit_index;
}
/**********************************************************************//**
Looks for a set bit in a record lock bitmap. Returns ULINT_UNDEFINED,
if none found.
@return bit index == heap number of the record, or ULINT_UNDEFINED if
none found */
UNIV_INTERN
ulint
lock_rec_find_set_bit(
/*==================*/
const lock_t* lock) /*!< in: record lock with at least one bit set */
{
ulint i;
for (i = 0; i < lock_rec_get_n_bits(lock); i++) {
if (lock_rec_get_nth_bit(lock, i)) {
return(i);
}
}
return(ULINT_UNDEFINED);
}
/**********************************************************************//**
Resets the nth bit of a record lock. */
UNIV_INLINE
void
lock_rec_reset_nth_bit(
/*===================*/
lock_t* lock, /*!< in: record lock */
ulint i) /*!< in: index of the bit which must be set to TRUE
when this function is called */
{
ulint byte_index;
ulint bit_index;
ut_ad(lock);
ut_ad(lock_get_type_low(lock) == LOCK_REC);
ut_ad(i < lock->un_member.rec_lock.n_bits);
byte_index = i / 8;
bit_index = i % 8;
((byte*) &lock[1])[byte_index] &= ~(1 << bit_index);
}
/*********************************************************************//**
Gets the first or next record lock on a page.
@return next lock, NULL if none exists */
UNIV_INLINE
lock_t*
lock_rec_get_next_on_page(
/*======================*/
lock_t* lock) /*!< in: a record lock */
{
ulint space;
ulint page_no;
ut_ad(mutex_own(&kernel_mutex));
ut_ad(lock_get_type_low(lock) == LOCK_REC);
space = lock->un_member.rec_lock.space;
page_no = lock->un_member.rec_lock.page_no;
for (;;) {
lock = HASH_GET_NEXT(hash, lock);
if (!lock) {
break;
}
if ((lock->un_member.rec_lock.space == space)
&& (lock->un_member.rec_lock.page_no == page_no)) {
break;
}
}
return(lock);
}
/*********************************************************************//**
Gets the first record lock on a page, where the page is identified by its
file address.
@return first lock, NULL if none exists */
UNIV_INLINE
lock_t*
lock_rec_get_first_on_page_addr(
/*============================*/
ulint space, /*!< in: space */
ulint page_no)/*!< in: page number */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
lock = HASH_GET_FIRST(lock_sys->rec_hash,
lock_rec_hash(space, page_no));
while (lock) {
if ((lock->un_member.rec_lock.space == space)
&& (lock->un_member.rec_lock.page_no == page_no)) {
break;
}
lock = HASH_GET_NEXT(hash, lock);
}
return(lock);
}
/*********************************************************************//**
Returns TRUE if there are explicit record locks on a page.
@return TRUE if there are explicit record locks on the page */
UNIV_INTERN
ibool
lock_rec_expl_exist_on_page(
/*========================*/
ulint space, /*!< in: space id */
ulint page_no)/*!< in: page number */
{
ibool ret;
mutex_enter(&kernel_mutex);
if (lock_rec_get_first_on_page_addr(space, page_no)) {
ret = TRUE;
} else {
ret = FALSE;
}
mutex_exit(&kernel_mutex);
return(ret);
}
/*********************************************************************//**
Gets the first record lock on a page, where the page is identified by a
pointer to it.
@return first lock, NULL if none exists */
UNIV_INLINE
lock_t*
lock_rec_get_first_on_page(
/*=======================*/
const buf_block_t* block) /*!< in: buffer block */
{
ulint hash;
lock_t* lock;
ulint space = buf_block_get_space(block);
ulint page_no = buf_block_get_page_no(block);
ut_ad(mutex_own(&kernel_mutex));
hash = buf_block_get_lock_hash_val(block);
lock = HASH_GET_FIRST(lock_sys->rec_hash, hash);
while (lock) {
if ((lock->un_member.rec_lock.space == space)
&& (lock->un_member.rec_lock.page_no == page_no)) {
break;
}
lock = HASH_GET_NEXT(hash, lock);
}
return(lock);
}
/*********************************************************************//**
Gets the next explicit lock request on a record.
@return next lock, NULL if none exists or if heap_no == ULINT_UNDEFINED */
UNIV_INLINE
lock_t*
lock_rec_get_next(
/*==============*/
ulint heap_no,/*!< in: heap number of the record */
lock_t* lock) /*!< in: lock */
{
ut_ad(mutex_own(&kernel_mutex));
do {
ut_ad(lock_get_type_low(lock) == LOCK_REC);
lock = lock_rec_get_next_on_page(lock);
} while (lock && !lock_rec_get_nth_bit(lock, heap_no));
return(lock);
}
/*********************************************************************//**
Gets the first explicit lock request on a record.
@return first lock, NULL if none exists */
UNIV_INLINE
lock_t*
lock_rec_get_first(
/*===============*/
const buf_block_t* block, /*!< in: block containing the record */
ulint heap_no)/*!< in: heap number of the record */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
for (lock = lock_rec_get_first_on_page(block); lock;
lock = lock_rec_get_next_on_page(lock)) {
if (lock_rec_get_nth_bit(lock, heap_no)) {
break;
}
}
return(lock);
}
/*********************************************************************//**
Resets the record lock bitmap to zero. NOTE: does not touch the wait_lock
pointer in the transaction! This function is used in lock object creation
and resetting. */
static
void
lock_rec_bitmap_reset(
/*==================*/
lock_t* lock) /*!< in: record lock */
{
ulint n_bytes;
ut_ad(lock_get_type_low(lock) == LOCK_REC);
/* Reset to zero the bitmap which resides immediately after the lock
struct */
n_bytes = lock_rec_get_n_bits(lock) / 8;
ut_ad((lock_rec_get_n_bits(lock) % 8) == 0);
memset(&lock[1], 0, n_bytes);
}
/*********************************************************************//**
Copies a record lock to heap.
@return copy of lock */
static
lock_t*
lock_rec_copy(
/*==========*/
const lock_t* lock, /*!< in: record lock */
mem_heap_t* heap) /*!< in: memory heap */
{
ulint size;
ut_ad(lock_get_type_low(lock) == LOCK_REC);
size = sizeof(lock_t) + lock_rec_get_n_bits(lock) / 8;
return(mem_heap_dup(heap, lock, size));
}
/*********************************************************************//**
Gets the previous record lock set on a record.
@return previous lock on the same record, NULL if none exists */
UNIV_INTERN
const lock_t*
lock_rec_get_prev(
/*==============*/
const lock_t* in_lock,/*!< in: record lock */
ulint heap_no)/*!< in: heap number of the record */
{
lock_t* lock;
ulint space;
ulint page_no;
lock_t* found_lock = NULL;
ut_ad(mutex_own(&kernel_mutex));
ut_ad(lock_get_type_low(in_lock) == LOCK_REC);
space = in_lock->un_member.rec_lock.space;
page_no = in_lock->un_member.rec_lock.page_no;
lock = lock_rec_get_first_on_page_addr(space, page_no);
for (;;) {
ut_ad(lock);
if (lock == in_lock) {
return(found_lock);
}
if (lock_rec_get_nth_bit(lock, heap_no)) {
found_lock = lock;
}
lock = lock_rec_get_next_on_page(lock);
}
}
/*============= FUNCTIONS FOR ANALYZING TABLE LOCK QUEUE ================*/
/*********************************************************************//**
Checks if a transaction has the specified table lock, or stronger.
@return lock or NULL */
UNIV_INLINE
lock_t*
lock_table_has(
/*===========*/
trx_t* trx, /*!< in: transaction */
dict_table_t* table, /*!< in: table */
enum lock_mode mode) /*!< in: lock mode */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
/* Look for stronger locks the same trx already has on the table */
lock = UT_LIST_GET_LAST(table->locks);
while (lock != NULL) {
if (lock->trx == trx
&& lock_mode_stronger_or_eq(lock_get_mode(lock), mode)) {
/* The same trx already has locked the table in
a mode stronger or equal to the mode given */
ut_ad(!lock_get_wait(lock));
return(lock);
}
lock = UT_LIST_GET_PREV(un_member.tab_lock.locks, lock);
}
return(NULL);
}
/*============= FUNCTIONS FOR ANALYZING RECORD LOCK QUEUE ================*/
/*********************************************************************//**
Checks if a transaction has a GRANTED explicit lock on rec stronger or equal
to precise_mode.
@return lock or NULL */
UNIV_INLINE
lock_t*
lock_rec_has_expl(
/*==============*/
ulint precise_mode,/*!< in: LOCK_S or LOCK_X
possibly ORed to LOCK_GAP or
LOCK_REC_NOT_GAP, for a
supremum record we regard this
always a gap type request */
const buf_block_t* block, /*!< in: buffer block containing
the record */
ulint heap_no,/*!< in: heap number of the record */
trx_t* trx) /*!< in: transaction */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
ut_ad((precise_mode & LOCK_MODE_MASK) == LOCK_S
|| (precise_mode & LOCK_MODE_MASK) == LOCK_X);
ut_ad(!(precise_mode & LOCK_INSERT_INTENTION));
lock = lock_rec_get_first(block, heap_no);
while (lock) {
if (lock->trx == trx
&& lock_mode_stronger_or_eq(lock_get_mode(lock),
precise_mode & LOCK_MODE_MASK)
&& !lock_get_wait(lock)
&& (!lock_rec_get_rec_not_gap(lock)
|| (precise_mode & LOCK_REC_NOT_GAP)
|| heap_no == PAGE_HEAP_NO_SUPREMUM)
&& (!lock_rec_get_gap(lock)
|| (precise_mode & LOCK_GAP)
|| heap_no == PAGE_HEAP_NO_SUPREMUM)
&& (!lock_rec_get_insert_intention(lock))) {
return(lock);
}
lock = lock_rec_get_next(heap_no, lock);
}
return(NULL);
}
#ifdef UNIV_DEBUG
/*********************************************************************//**
Checks if some other transaction has a lock request in the queue.
@return lock or NULL */
static
lock_t*
lock_rec_other_has_expl_req(
/*========================*/
enum lock_mode mode, /*!< in: LOCK_S or LOCK_X */
ulint gap, /*!< in: LOCK_GAP if also gap
locks are taken into account,
or 0 if not */
ulint wait, /*!< in: LOCK_WAIT if also
waiting locks are taken into
account, or 0 if not */
const buf_block_t* block, /*!< in: buffer block containing
the record */
ulint heap_no,/*!< in: heap number of the record */
const trx_t* trx) /*!< in: transaction, or NULL if
requests by all transactions
are taken into account */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
ut_ad(mode == LOCK_X || mode == LOCK_S);
ut_ad(gap == 0 || gap == LOCK_GAP);
ut_ad(wait == 0 || wait == LOCK_WAIT);
lock = lock_rec_get_first(block, heap_no);
while (lock) {
if (lock->trx != trx
&& (gap
|| !(lock_rec_get_gap(lock)
|| heap_no == PAGE_HEAP_NO_SUPREMUM))
&& (wait || !lock_get_wait(lock))
&& lock_mode_stronger_or_eq(lock_get_mode(lock), mode)) {
return(lock);
}
lock = lock_rec_get_next(heap_no, lock);
}
return(NULL);
}
#endif /* UNIV_DEBUG */
/*********************************************************************//**
Checks if some other transaction has a conflicting explicit lock request
in the queue, so that we have to wait.
@return lock or NULL */
static
lock_t*
lock_rec_other_has_conflicting(
/*===========================*/
enum lock_mode mode, /*!< in: LOCK_S or LOCK_X,
possibly ORed to LOCK_GAP or
LOC_REC_NOT_GAP,
LOCK_INSERT_INTENTION */
const buf_block_t* block, /*!< in: buffer block containing
the record */
ulint heap_no,/*!< in: heap number of the record */
trx_t* trx) /*!< in: our transaction */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
lock = lock_rec_get_first(block, heap_no);
if (UNIV_LIKELY_NULL(lock)) {
if (UNIV_UNLIKELY(heap_no == PAGE_HEAP_NO_SUPREMUM)) {
do {
if (lock_rec_has_to_wait(trx, mode, lock,
TRUE)) {
return(lock);
}
lock = lock_rec_get_next(heap_no, lock);
} while (lock);
} else {
do {
if (lock_rec_has_to_wait(trx, mode, lock,
FALSE)) {
return(lock);
}
lock = lock_rec_get_next(heap_no, lock);
} while (lock);
}
}
return(NULL);
}
/*********************************************************************//**
Looks for a suitable type record lock struct by the same trx on the same page.
This can be used to save space when a new record lock should be set on a page:
no new struct is needed, if a suitable old is found.
@return lock or NULL */
UNIV_INLINE
lock_t*
lock_rec_find_similar_on_page(
/*==========================*/
ulint type_mode, /*!< in: lock type_mode field */
ulint heap_no, /*!< in: heap number of the record */
lock_t* lock, /*!< in: lock_rec_get_first_on_page() */
const trx_t* trx) /*!< in: transaction */
{
ut_ad(mutex_own(&kernel_mutex));
while (lock != NULL) {
if (lock->trx == trx
&& lock->type_mode == type_mode
&& lock_rec_get_n_bits(lock) > heap_no) {
return(lock);
}
lock = lock_rec_get_next_on_page(lock);
}
return(NULL);
}
/*********************************************************************//**
Checks if some transaction has an implicit x-lock on a record in a secondary
index.
@return transaction which has the x-lock, or NULL */
static
trx_t*
lock_sec_rec_some_has_impl_off_kernel(
/*==================================*/
const rec_t* rec, /*!< in: user record */
dict_index_t* index, /*!< in: secondary index */
const ulint* offsets)/*!< in: rec_get_offsets(rec, index) */
{
const page_t* page = page_align(rec);
ut_ad(mutex_own(&kernel_mutex));
ut_ad(!dict_index_is_clust(index));
ut_ad(page_rec_is_user_rec(rec));
ut_ad(rec_offs_validate(rec, index, offsets));
/* Some transaction may have an implicit x-lock on the record only
if the max trx id for the page >= min trx id for the trx list, or
database recovery is running. We do not write the changes of a page
max trx id to the log, and therefore during recovery, this value
for a page may be incorrect. */
if (!(ut_dulint_cmp(page_get_max_trx_id(page),
trx_list_get_min_trx_id()) >= 0)
&& !recv_recovery_is_on()) {
return(NULL);
}
/* Ok, in this case it is possible that some transaction has an
implicit x-lock. We have to look in the clustered index. */
if (!lock_check_trx_id_sanity(page_get_max_trx_id(page),
rec, index, offsets, TRUE)) {
buf_page_print(page, 0);
/* The page is corrupt: try to avoid a crash by returning
NULL */
return(NULL);
}
return(row_vers_impl_x_locked_off_kernel(rec, index, offsets));
}
/*********************************************************************//**
Return approximate number or record locks (bits set in the bitmap) for
this transaction. Since delete-marked records may be removed, the
record count will not be precise. */
UNIV_INTERN
ulint
lock_number_of_rows_locked(
/*=======================*/
trx_t* trx) /*!< in: transaction */
{
lock_t* lock;
ulint n_records = 0;
ulint n_bits;
ulint n_bit;
lock = UT_LIST_GET_FIRST(trx->trx_locks);
while (lock) {
if (lock_get_type_low(lock) == LOCK_REC) {
n_bits = lock_rec_get_n_bits(lock);
for (n_bit = 0; n_bit < n_bits; n_bit++) {
if (lock_rec_get_nth_bit(lock, n_bit)) {
n_records++;
}
}
}
lock = UT_LIST_GET_NEXT(trx_locks, lock);
}
return (n_records);
}
/*============== RECORD LOCK CREATION AND QUEUE MANAGEMENT =============*/
/*********************************************************************//**
Creates a new record lock and inserts it to the lock queue. Does NOT check
for deadlocks or lock compatibility!
@return created lock */
static
lock_t*
lock_rec_create(
/*============*/
ulint type_mode,/*!< in: lock mode and wait
flag, type is ignored and
replaced by LOCK_REC */
const buf_block_t* block, /*!< in: buffer block containing
the record */
ulint heap_no,/*!< in: heap number of the record */
dict_index_t* index, /*!< in: index of record */
trx_t* trx) /*!< in: transaction */
{
lock_t* lock;
ulint page_no;
ulint space;
ulint n_bits;
ulint n_bytes;
const page_t* page;
ut_ad(mutex_own(&kernel_mutex));
space = buf_block_get_space(block);
page_no = buf_block_get_page_no(block);
page = block->frame;
ut_ad(!!page_is_comp(page) == dict_table_is_comp(index->table));
/* If rec is the supremum record, then we reset the gap and
LOCK_REC_NOT_GAP bits, as all locks on the supremum are
automatically of the gap type */
if (UNIV_UNLIKELY(heap_no == PAGE_HEAP_NO_SUPREMUM)) {
ut_ad(!(type_mode & LOCK_REC_NOT_GAP));
type_mode = type_mode & ~(LOCK_GAP | LOCK_REC_NOT_GAP);
}
/* Make lock bitmap bigger by a safety margin */
n_bits = page_dir_get_n_heap(page) + LOCK_PAGE_BITMAP_MARGIN;
n_bytes = 1 + n_bits / 8;
lock = mem_heap_alloc(trx->lock_heap, sizeof(lock_t) + n_bytes);
UT_LIST_ADD_LAST(trx_locks, trx->trx_locks, lock);
lock->trx = trx;
lock->type_mode = (type_mode & ~LOCK_TYPE_MASK) | LOCK_REC;
lock->index = index;
lock->un_member.rec_lock.space = space;
lock->un_member.rec_lock.page_no = page_no;
lock->un_member.rec_lock.n_bits = n_bytes * 8;
/* Reset to zero the bitmap which resides immediately after the
lock struct */
lock_rec_bitmap_reset(lock);
/* Set the bit corresponding to rec */
lock_rec_set_nth_bit(lock, heap_no);
HASH_INSERT(lock_t, hash, lock_sys->rec_hash,
lock_rec_fold(space, page_no), lock);
if (UNIV_UNLIKELY(type_mode & LOCK_WAIT)) {
lock_set_lock_and_trx_wait(lock, trx);
}
return(lock);
}
/*********************************************************************//**
Enqueues a waiting request for a lock which cannot be granted immediately.
Checks for deadlocks.
@return DB_LOCK_WAIT, DB_DEADLOCK, or DB_QUE_THR_SUSPENDED, or
DB_SUCCESS_LOCKED_REC; DB_SUCCESS_LOCKED_REC means that
there was a deadlock, but another transaction was chosen as a victim,
and we got the lock immediately: no need to wait then */
static
enum db_err
lock_rec_enqueue_waiting(
/*=====================*/
ulint type_mode,/*!< in: lock mode this
transaction is requesting:
LOCK_S or LOCK_X, possibly
ORed with LOCK_GAP or
LOCK_REC_NOT_GAP, ORed with
LOCK_INSERT_INTENTION if this
waiting lock request is set
when performing an insert of
an index record */
const buf_block_t* block, /*!< in: buffer block containing
the record */
ulint heap_no,/*!< in: heap number of the record */
dict_index_t* index, /*!< in: index of record */
que_thr_t* thr) /*!< in: query thread */
{
lock_t* lock;
trx_t* trx;
ulint sec;
ulint ms;
ut_ad(mutex_own(&kernel_mutex));
/* Test if there already is some other reason to suspend thread:
we do not enqueue a lock request if the query thread should be
stopped anyway */
if (UNIV_UNLIKELY(que_thr_stop(thr))) {
ut_error;
return(DB_QUE_THR_SUSPENDED);
}
trx = thr_get_trx(thr);
switch (trx_get_dict_operation(trx)) {
case TRX_DICT_OP_NONE:
break;
case TRX_DICT_OP_TABLE:
case TRX_DICT_OP_INDEX:
ut_print_timestamp(stderr);
fputs(" InnoDB: Error: a record lock wait happens"
" in a dictionary operation!\n"
"InnoDB: ", stderr);
dict_index_name_print(stderr, trx, index);
fputs(".\n"
"InnoDB: Submit a detailed bug report"
" to http://bugs.mysql.com\n",
stderr);
}
/* Enqueue the lock request that will wait to be granted */
lock = lock_rec_create(type_mode | LOCK_WAIT,
block, heap_no, index, trx);
/* Check if a deadlock occurs: if yes, remove the lock request and
return an error code */
if (UNIV_UNLIKELY(lock_deadlock_occurs(lock, trx))) {
lock_reset_lock_and_trx_wait(lock);
lock_rec_reset_nth_bit(lock, heap_no);
return(DB_DEADLOCK);
}
/* If there was a deadlock but we chose another transaction as a
victim, it is possible that we already have the lock now granted! */
if (trx->wait_lock == NULL) {
return(DB_SUCCESS_LOCKED_REC);
}
trx->que_state = TRX_QUE_LOCK_WAIT;
trx->was_chosen_as_deadlock_victim = FALSE;
trx->wait_started = time(NULL);
if (innobase_get_slow_log() && trx->take_stats) {
ut_usectime(&sec, &ms);
trx->lock_que_wait_ustarted = (ib_uint64_t)sec * 1000000 + ms;
}
ut_a(que_thr_stop(thr));
#ifdef UNIV_DEBUG
if (lock_print_waits) {
fprintf(stderr, "Lock wait for trx %lu in index ",
(ulong) ut_dulint_get_low(trx->id));
ut_print_name(stderr, trx, FALSE, index->name);
}
#endif /* UNIV_DEBUG */
return(DB_LOCK_WAIT);
}
/*********************************************************************//**
Adds a record lock request in the record queue. The request is normally
added as the last in the queue, but if there are no waiting lock requests
on the record, and the request to be added is not a waiting request, we
can reuse a suitable record lock object already existing on the same page,
just setting the appropriate bit in its bitmap. This is a low-level function
which does NOT check for deadlocks or lock compatibility!
@return lock where the bit was set */
static
lock_t*
lock_rec_add_to_queue(
/*==================*/
ulint type_mode,/*!< in: lock mode, wait, gap
etc. flags; type is ignored
and replaced by LOCK_REC */
const buf_block_t* block, /*!< in: buffer block containing
the record */
ulint heap_no,/*!< in: heap number of the record */
dict_index_t* index, /*!< in: index of record */
trx_t* trx) /*!< in: transaction */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
#ifdef UNIV_DEBUG
switch (type_mode & LOCK_MODE_MASK) {
case LOCK_X:
case LOCK_S:
break;
default:
ut_error;
}
if (!(type_mode & (LOCK_WAIT | LOCK_GAP))) {
enum lock_mode mode = (type_mode & LOCK_MODE_MASK) == LOCK_S
? LOCK_X
: LOCK_S;
lock_t* other_lock
= lock_rec_other_has_expl_req(mode, 0, LOCK_WAIT,
block, heap_no, trx);
ut_a(!other_lock);
}
#endif /* UNIV_DEBUG */
type_mode |= LOCK_REC;
/* If rec is the supremum record, then we can reset the gap bit, as
all locks on the supremum are automatically of the gap type, and we
try to avoid unnecessary memory consumption of a new record lock
struct for a gap type lock */
if (UNIV_UNLIKELY(heap_no == PAGE_HEAP_NO_SUPREMUM)) {
ut_ad(!(type_mode & LOCK_REC_NOT_GAP));
/* There should never be LOCK_REC_NOT_GAP on a supremum
record, but let us play safe */
type_mode = type_mode & ~(LOCK_GAP | LOCK_REC_NOT_GAP);
}
/* Look for a waiting lock request on the same record or on a gap */
lock = lock_rec_get_first_on_page(block);
while (lock != NULL) {
if (lock_get_wait(lock)
&& (lock_rec_get_nth_bit(lock, heap_no))) {
goto somebody_waits;
}
lock = lock_rec_get_next_on_page(lock);
}
if (UNIV_LIKELY(!(type_mode & LOCK_WAIT))) {
/* Look for a similar record lock on the same page:
if one is found and there are no waiting lock requests,
we can just set the bit */
lock = lock_rec_find_similar_on_page(
type_mode, heap_no,
lock_rec_get_first_on_page(block), trx);
if (lock) {
lock_rec_set_nth_bit(lock, heap_no);
return(lock);
}
}
somebody_waits:
return(lock_rec_create(type_mode, block, heap_no, index, trx));
}
/** Record locking request status */
enum lock_rec_req_status {
/** Failed to acquire a lock */
LOCK_REC_FAIL,
/** Succeeded in acquiring a lock (implicit or already acquired) */
LOCK_REC_SUCCESS,
/** Explicitly created a new lock */
LOCK_REC_SUCCESS_CREATED
};
/*********************************************************************//**
This is a fast routine for locking a record in the most common cases:
there are no explicit locks on the page, or there is just one lock, owned
by this transaction, and of the right type_mode. This is a low-level function
which does NOT look at implicit locks! Checks lock compatibility within
explicit locks. This function sets a normal next-key lock, or in the case of
a page supremum record, a gap type lock.
@return whether the locking succeeded */
UNIV_INLINE
enum lock_rec_req_status
lock_rec_lock_fast(
/*===============*/
ibool impl, /*!< in: if TRUE, no lock is set
if no wait is necessary: we
assume that the caller will
set an implicit lock */
ulint mode, /*!< in: lock mode: LOCK_X or
LOCK_S possibly ORed to either
LOCK_GAP or LOCK_REC_NOT_GAP */
const buf_block_t* block, /*!< in: buffer block containing
the record */
ulint heap_no,/*!< in: heap number of record */
dict_index_t* index, /*!< in: index of record */
que_thr_t* thr) /*!< in: query thread */
{
lock_t* lock;
trx_t* trx;
ut_ad(mutex_own(&kernel_mutex));
ut_ad((LOCK_MODE_MASK & mode) != LOCK_S
|| lock_table_has(thr_get_trx(thr), index->table, LOCK_IS));
ut_ad((LOCK_MODE_MASK & mode) != LOCK_X
|| lock_table_has(thr_get_trx(thr), index->table, LOCK_IX));
ut_ad((LOCK_MODE_MASK & mode) == LOCK_S
|| (LOCK_MODE_MASK & mode) == LOCK_X);
ut_ad(mode - (LOCK_MODE_MASK & mode) == LOCK_GAP
|| mode - (LOCK_MODE_MASK & mode) == 0
|| mode - (LOCK_MODE_MASK & mode) == LOCK_REC_NOT_GAP);
lock = lock_rec_get_first_on_page(block);
trx = thr_get_trx(thr);
if (lock == NULL) {
if (!impl) {
lock_rec_create(mode, block, heap_no, index, trx);
}
return(LOCK_REC_SUCCESS_CREATED);
}
if (lock_rec_get_next_on_page(lock)) {
return(LOCK_REC_FAIL);
}
if (lock->trx != trx
|| lock->type_mode != (mode | LOCK_REC)
|| lock_rec_get_n_bits(lock) <= heap_no) {
return(LOCK_REC_FAIL);
}
if (!impl) {
/* If the nth bit of the record lock is already set then we
do not set a new lock bit, otherwise we do set */
if (!lock_rec_get_nth_bit(lock, heap_no)) {
lock_rec_set_nth_bit(lock, heap_no);
return(LOCK_REC_SUCCESS_CREATED);
}
}
return(LOCK_REC_SUCCESS);
}
/*********************************************************************//**
This is the general, and slower, routine for locking a record. This is a
low-level function which does NOT look at implicit locks! Checks lock
compatibility within explicit locks. This function sets a normal next-key
lock, or in the case of a page supremum record, a gap type lock.
@return DB_SUCCESS, DB_SUCCESS_LOCKED_REC, DB_LOCK_WAIT, DB_DEADLOCK,
or DB_QUE_THR_SUSPENDED */
static
enum db_err
lock_rec_lock_slow(
/*===============*/
ibool impl, /*!< in: if TRUE, no lock is set
if no wait is necessary: we
assume that the caller will
set an implicit lock */
ulint mode, /*!< in: lock mode: LOCK_X or
LOCK_S possibly ORed to either
LOCK_GAP or LOCK_REC_NOT_GAP */
const buf_block_t* block, /*!< in: buffer block containing
the record */
ulint heap_no,/*!< in: heap number of record */
dict_index_t* index, /*!< in: index of record */
que_thr_t* thr) /*!< in: query thread */
{
trx_t* trx;
ut_ad(mutex_own(&kernel_mutex));
ut_ad((LOCK_MODE_MASK & mode) != LOCK_S
|| lock_table_has(thr_get_trx(thr), index->table, LOCK_IS));
ut_ad((LOCK_MODE_MASK & mode) != LOCK_X
|| lock_table_has(thr_get_trx(thr), index->table, LOCK_IX));
ut_ad((LOCK_MODE_MASK & mode) == LOCK_S
|| (LOCK_MODE_MASK & mode) == LOCK_X);
ut_ad(mode - (LOCK_MODE_MASK & mode) == LOCK_GAP
|| mode - (LOCK_MODE_MASK & mode) == 0
|| mode - (LOCK_MODE_MASK & mode) == LOCK_REC_NOT_GAP);
trx = thr_get_trx(thr);
if (lock_rec_has_expl(mode, block, heap_no, trx)) {
/* The trx already has a strong enough lock on rec: do
nothing */
} else if (lock_rec_other_has_conflicting(mode, block, heap_no, trx)) {
/* If another transaction has a non-gap conflicting request in
the queue, as this transaction does not have a lock strong
enough already granted on the record, we have to wait. */
return(lock_rec_enqueue_waiting(mode, block, heap_no,
index, thr));
} else if (!impl) {
/* Set the requested lock on the record */
lock_rec_add_to_queue(LOCK_REC | mode, block,
heap_no, index, trx);
return(DB_SUCCESS_LOCKED_REC);
}
return(DB_SUCCESS);
}
/*********************************************************************//**
Tries to lock the specified record in the mode requested. If not immediately
possible, enqueues a waiting lock request. This is a low-level function
which does NOT look at implicit locks! Checks lock compatibility within
explicit locks. This function sets a normal next-key lock, or in the case
of a page supremum record, a gap type lock.
@return DB_SUCCESS, DB_SUCCESS_LOCKED_REC, DB_LOCK_WAIT, DB_DEADLOCK,
or DB_QUE_THR_SUSPENDED */
static
enum db_err
lock_rec_lock(
/*==========*/
ibool impl, /*!< in: if TRUE, no lock is set
if no wait is necessary: we
assume that the caller will
set an implicit lock */
ulint mode, /*!< in: lock mode: LOCK_X or
LOCK_S possibly ORed to either
LOCK_GAP or LOCK_REC_NOT_GAP */
const buf_block_t* block, /*!< in: buffer block containing
the record */
ulint heap_no,/*!< in: heap number of record */
dict_index_t* index, /*!< in: index of record */
que_thr_t* thr) /*!< in: query thread */
{
ut_ad(mutex_own(&kernel_mutex));
ut_ad((LOCK_MODE_MASK & mode) != LOCK_S
|| lock_table_has(thr_get_trx(thr), index->table, LOCK_IS));
ut_ad((LOCK_MODE_MASK & mode) != LOCK_X
|| lock_table_has(thr_get_trx(thr), index->table, LOCK_IX));
ut_ad((LOCK_MODE_MASK & mode) == LOCK_S
|| (LOCK_MODE_MASK & mode) == LOCK_X);
ut_ad(mode - (LOCK_MODE_MASK & mode) == LOCK_GAP
|| mode - (LOCK_MODE_MASK & mode) == LOCK_REC_NOT_GAP
|| mode - (LOCK_MODE_MASK & mode) == 0);
/* We try a simplified and faster subroutine for the most
common cases */
switch (lock_rec_lock_fast(impl, mode, block, heap_no, index, thr)) {
case LOCK_REC_SUCCESS:
return(DB_SUCCESS);
case LOCK_REC_SUCCESS_CREATED:
return(DB_SUCCESS_LOCKED_REC);
case LOCK_REC_FAIL:
return(lock_rec_lock_slow(impl, mode, block,
heap_no, index, thr));
}
ut_error;
return(DB_ERROR);
}
/*********************************************************************//**
Checks if a waiting record lock request still has to wait in a queue.
@return TRUE if still has to wait */
static
ibool
lock_rec_has_to_wait_in_queue(
/*==========================*/
lock_t* wait_lock) /*!< in: waiting record lock */
{
lock_t* lock;
ulint space;
ulint page_no;
ulint heap_no;
ut_ad(mutex_own(&kernel_mutex));
ut_ad(lock_get_wait(wait_lock));
ut_ad(lock_get_type_low(wait_lock) == LOCK_REC);
space = wait_lock->un_member.rec_lock.space;
page_no = wait_lock->un_member.rec_lock.page_no;
heap_no = lock_rec_find_set_bit(wait_lock);
lock = lock_rec_get_first_on_page_addr(space, page_no);
while (lock != wait_lock) {
if (lock_rec_get_nth_bit(lock, heap_no)
&& lock_has_to_wait(wait_lock, lock)) {
return(TRUE);
}
lock = lock_rec_get_next_on_page(lock);
}
return(FALSE);
}
/*************************************************************//**
Grants a lock to a waiting lock request and releases the waiting
transaction. */
static
void
lock_grant(
/*=======*/
lock_t* lock) /*!< in/out: waiting lock request */
{
ut_ad(mutex_own(&kernel_mutex));
lock_reset_lock_and_trx_wait(lock);
if (lock_get_mode(lock) == LOCK_AUTO_INC) {
trx_t* trx = lock->trx;
dict_table_t* table = lock->un_member.tab_lock.table;
if (table->autoinc_trx == trx) {
fprintf(stderr,
"InnoDB: Error: trx already had"
" an AUTO-INC lock!\n");
} else {
table->autoinc_trx = trx;
ib_vector_push(trx->autoinc_locks, lock);
}
}
#ifdef UNIV_DEBUG
if (lock_print_waits) {
fprintf(stderr, "Lock wait for trx %lu ends\n",
(ulong) ut_dulint_get_low(lock->trx->id));
}
#endif /* UNIV_DEBUG */
/* If we are resolving a deadlock by choosing another transaction
as a victim, then our original transaction may not be in the
TRX_QUE_LOCK_WAIT state, and there is no need to end the lock wait
for it */
if (lock->trx->que_state == TRX_QUE_LOCK_WAIT) {
trx_end_lock_wait(lock->trx);
}
}
/*************************************************************//**
Cancels a waiting record lock request and releases the waiting transaction
that requested it. NOTE: does NOT check if waiting lock requests behind this
one can now be granted! */
static
void
lock_rec_cancel(
/*============*/
lock_t* lock) /*!< in: waiting record lock request */
{
ut_ad(mutex_own(&kernel_mutex));
ut_ad(lock_get_type_low(lock) == LOCK_REC);
/* Reset the bit (there can be only one set bit) in the lock bitmap */
lock_rec_reset_nth_bit(lock, lock_rec_find_set_bit(lock));
/* Reset the wait flag and the back pointer to lock in trx */
lock_reset_lock_and_trx_wait(lock);
/* The following function releases the trx from lock wait */
trx_end_lock_wait(lock->trx);
}
/*************************************************************//**
Removes a record lock request, waiting or granted, from the queue and
grants locks to other transactions in the queue if they now are entitled
to a lock. NOTE: all record locks contained in in_lock are removed. */
static
void
lock_rec_dequeue_from_page(
/*=======================*/
lock_t* in_lock)/*!< in: record lock object: all record locks which
are contained in this lock object are removed;
transactions waiting behind will get their lock
requests granted, if they are now qualified to it */
{
ulint space;
ulint page_no;
lock_t* lock;
trx_t* trx;
ut_ad(mutex_own(&kernel_mutex));
ut_ad(lock_get_type_low(in_lock) == LOCK_REC);
trx = in_lock->trx;
space = in_lock->un_member.rec_lock.space;
page_no = in_lock->un_member.rec_lock.page_no;
HASH_DELETE(lock_t, hash, lock_sys->rec_hash,
lock_rec_fold(space, page_no), in_lock);
UT_LIST_REMOVE(trx_locks, trx->trx_locks, in_lock);
/* Check if waiting locks in the queue can now be granted: grant
locks if there are no conflicting locks ahead. */
lock = lock_rec_get_first_on_page_addr(space, page_no);
while (lock != NULL) {
if (lock_get_wait(lock)
&& !lock_rec_has_to_wait_in_queue(lock)) {
/* Grant the lock */
lock_grant(lock);
}
lock = lock_rec_get_next_on_page(lock);
}
}
/*************************************************************//**
Removes a record lock request, waiting or granted, from the queue. */
static
void
lock_rec_discard(
/*=============*/
lock_t* in_lock)/*!< in: record lock object: all record locks which
are contained in this lock object are removed */
{
ulint space;
ulint page_no;
trx_t* trx;
ut_ad(mutex_own(&kernel_mutex));
ut_ad(lock_get_type_low(in_lock) == LOCK_REC);
trx = in_lock->trx;
space = in_lock->un_member.rec_lock.space;
page_no = in_lock->un_member.rec_lock.page_no;
HASH_DELETE(lock_t, hash, lock_sys->rec_hash,
lock_rec_fold(space, page_no), in_lock);
UT_LIST_REMOVE(trx_locks, trx->trx_locks, in_lock);
}
/*************************************************************//**
Removes record lock objects set on an index page which is discarded. This
function does not move locks, or check for waiting locks, therefore the
lock bitmaps must already be reset when this function is called. */
static
void
lock_rec_free_all_from_discard_page(
/*================================*/
const buf_block_t* block) /*!< in: page to be discarded */
{
ulint space;
ulint page_no;
lock_t* lock;
lock_t* next_lock;
ut_ad(mutex_own(&kernel_mutex));
space = buf_block_get_space(block);
page_no = buf_block_get_page_no(block);
lock = lock_rec_get_first_on_page_addr(space, page_no);
while (lock != NULL) {
ut_ad(lock_rec_find_set_bit(lock) == ULINT_UNDEFINED);
ut_ad(!lock_get_wait(lock));
next_lock = lock_rec_get_next_on_page(lock);
lock_rec_discard(lock);
lock = next_lock;
}
}
/*============= RECORD LOCK MOVING AND INHERITING ===================*/
/*************************************************************//**
Resets the lock bits for a single record. Releases transactions waiting for
lock requests here. */
static
void
lock_rec_reset_and_release_wait(
/*============================*/
const buf_block_t* block, /*!< in: buffer block containing
the record */
ulint heap_no)/*!< in: heap number of record */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
lock = lock_rec_get_first(block, heap_no);
while (lock != NULL) {
if (lock_get_wait(lock)) {
lock_rec_cancel(lock);
} else {
lock_rec_reset_nth_bit(lock, heap_no);
}
lock = lock_rec_get_next(heap_no, lock);
}
}
/*************************************************************//**
Makes a record to inherit the locks (except LOCK_INSERT_INTENTION type)
of another record as gap type locks, but does not reset the lock bits of
the other record. Also waiting lock requests on rec are inherited as
GRANTED gap locks. */
static
void
lock_rec_inherit_to_gap(
/*====================*/
const buf_block_t* heir_block, /*!< in: block containing the
record which inherits */
const buf_block_t* block, /*!< in: block containing the
record from which inherited;
does NOT reset the locks on
this record */
ulint heir_heap_no, /*!< in: heap_no of the
inheriting record */
ulint heap_no) /*!< in: heap_no of the
donating record */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
lock = lock_rec_get_first(block, heap_no);
/* If srv_locks_unsafe_for_binlog is TRUE or session is using
READ COMMITTED isolation level, we do not want locks set
by an UPDATE or a DELETE to be inherited as gap type locks. But we
DO want S-locks set by a consistency constraint to be inherited also
then. */
while (lock != NULL) {
if (!lock_rec_get_insert_intention(lock)
&& !((srv_locks_unsafe_for_binlog
|| lock->trx->isolation_level
<= TRX_ISO_READ_COMMITTED)
&& lock_get_mode(lock) == LOCK_X)) {
lock_rec_add_to_queue(LOCK_REC | LOCK_GAP
| lock_get_mode(lock),
heir_block, heir_heap_no,
lock->index, lock->trx);
}
lock = lock_rec_get_next(heap_no, lock);
}
}
/*************************************************************//**
Makes a record to inherit the gap locks (except LOCK_INSERT_INTENTION type)
of another record as gap type locks, but does not reset the lock bits of the
other record. Also waiting lock requests are inherited as GRANTED gap locks. */
static
void
lock_rec_inherit_to_gap_if_gap_lock(
/*================================*/
const buf_block_t* block, /*!< in: buffer block */
ulint heir_heap_no, /*!< in: heap_no of
record which inherits */
ulint heap_no) /*!< in: heap_no of record
from which inherited;
does NOT reset the locks
on this record */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
lock = lock_rec_get_first(block, heap_no);
while (lock != NULL) {
if (!lock_rec_get_insert_intention(lock)
&& (heap_no == PAGE_HEAP_NO_SUPREMUM
|| !lock_rec_get_rec_not_gap(lock))) {
lock_rec_add_to_queue(LOCK_REC | LOCK_GAP
| lock_get_mode(lock),
block, heir_heap_no,
lock->index, lock->trx);
}
lock = lock_rec_get_next(heap_no, lock);
}
}
/*************************************************************//**
Moves the locks of a record to another record and resets the lock bits of
the donating record. */
static
void
lock_rec_move(
/*==========*/
const buf_block_t* receiver, /*!< in: buffer block containing
the receiving record */
const buf_block_t* donator, /*!< in: buffer block containing
the donating record */
ulint receiver_heap_no,/*!< in: heap_no of the record
which gets the locks; there
must be no lock requests
on it! */
ulint donator_heap_no)/*!< in: heap_no of the record
which gives the locks */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
lock = lock_rec_get_first(donator, donator_heap_no);
ut_ad(lock_rec_get_first(receiver, receiver_heap_no) == NULL);
while (lock != NULL) {
const ulint type_mode = lock->type_mode;
lock_rec_reset_nth_bit(lock, donator_heap_no);
if (UNIV_UNLIKELY(type_mode & LOCK_WAIT)) {
lock_reset_lock_and_trx_wait(lock);
}
/* Note that we FIRST reset the bit, and then set the lock:
the function works also if donator == receiver */
lock_rec_add_to_queue(type_mode, receiver, receiver_heap_no,
lock->index, lock->trx);
lock = lock_rec_get_next(donator_heap_no, lock);
}
ut_ad(lock_rec_get_first(donator, donator_heap_no) == NULL);
}
/*************************************************************//**
Updates the lock table when we have reorganized a page. NOTE: we copy
also the locks set on the infimum of the page; the infimum may carry
locks if an update of a record is occurring on the page, and its locks
were temporarily stored on the infimum. */
UNIV_INTERN
void
lock_move_reorganize_page(
/*======================*/
const buf_block_t* block, /*!< in: old index page, now
reorganized */
const buf_block_t* oblock) /*!< in: copy of the old, not
reorganized page */
{
lock_t* lock;
UT_LIST_BASE_NODE_T(lock_t) old_locks;
mem_heap_t* heap = NULL;
ulint comp;
lock_mutex_enter_kernel();
lock = lock_rec_get_first_on_page(block);
if (lock == NULL) {
lock_mutex_exit_kernel();
return;
}
heap = mem_heap_create(256);
/* Copy first all the locks on the page to heap and reset the
bitmaps in the original locks; chain the copies of the locks
using the trx_locks field in them. */
UT_LIST_INIT(old_locks);
do {
/* Make a copy of the lock */
lock_t* old_lock = lock_rec_copy(lock, heap);
UT_LIST_ADD_LAST(trx_locks, old_locks, old_lock);
/* Reset bitmap of lock */
lock_rec_bitmap_reset(lock);
if (lock_get_wait(lock)) {
lock_reset_lock_and_trx_wait(lock);
}
lock = lock_rec_get_next_on_page(lock);
} while (lock != NULL);
comp = page_is_comp(block->frame);
ut_ad(comp == page_is_comp(oblock->frame));
for (lock = UT_LIST_GET_FIRST(old_locks); lock;
lock = UT_LIST_GET_NEXT(trx_locks, lock)) {
/* NOTE: we copy also the locks set on the infimum and
supremum of the page; the infimum may carry locks if an
update of a record is occurring on the page, and its locks
were temporarily stored on the infimum */
page_cur_t cur1;
page_cur_t cur2;
page_cur_set_before_first(block, &cur1);
page_cur_set_before_first(oblock, &cur2);
/* Set locks according to old locks */
for (;;) {
ulint old_heap_no;
ulint new_heap_no;
ut_ad(comp || !memcmp(page_cur_get_rec(&cur1),
page_cur_get_rec(&cur2),
rec_get_data_size_old(
page_cur_get_rec(
&cur2))));
if (UNIV_LIKELY(comp)) {
old_heap_no = rec_get_heap_no_new(
page_cur_get_rec(&cur2));
new_heap_no = rec_get_heap_no_new(
page_cur_get_rec(&cur1));
} else {
old_heap_no = rec_get_heap_no_old(
page_cur_get_rec(&cur2));
new_heap_no = rec_get_heap_no_old(
page_cur_get_rec(&cur1));
}
if (lock_rec_get_nth_bit(lock, old_heap_no)) {
/* Clear the bit in old_lock. */
ut_d(lock_rec_reset_nth_bit(lock,
old_heap_no));
/* NOTE that the old lock bitmap could be too
small for the new heap number! */
lock_rec_add_to_queue(lock->type_mode, block,
new_heap_no,
lock->index, lock->trx);
/* if (new_heap_no == PAGE_HEAP_NO_SUPREMUM
&& lock_get_wait(lock)) {
fprintf(stderr,
"---\n--\n!!!Lock reorg: supr type %lu\n",
lock->type_mode);
} */
}
if (UNIV_UNLIKELY
(new_heap_no == PAGE_HEAP_NO_SUPREMUM)) {
ut_ad(old_heap_no == PAGE_HEAP_NO_SUPREMUM);
break;
}
page_cur_move_to_next(&cur1);
page_cur_move_to_next(&cur2);
}
#ifdef UNIV_DEBUG
{
ulint i = lock_rec_find_set_bit(lock);
/* Check that all locks were moved. */
if (UNIV_UNLIKELY(i != ULINT_UNDEFINED)) {
fprintf(stderr,
"lock_move_reorganize_page():"
" %lu not moved in %p\n",
(ulong) i, (void*) lock);
ut_error;
}
}
#endif /* UNIV_DEBUG */
}
lock_mutex_exit_kernel();
mem_heap_free(heap);
#ifdef UNIV_DEBUG_LOCK_VALIDATE
ut_ad(lock_rec_validate_page(buf_block_get_space(block),
buf_block_get_zip_size(block),
buf_block_get_page_no(block)));
#endif
}
/*************************************************************//**
Moves the explicit locks on user records to another page if a record
list end is moved to another page. */
UNIV_INTERN
void
lock_move_rec_list_end(
/*===================*/
const buf_block_t* new_block, /*!< in: index page to move to */
const buf_block_t* block, /*!< in: index page */
const rec_t* rec) /*!< in: record on page: this
is the first record moved */
{
lock_t* lock;
const ulint comp = page_rec_is_comp(rec);
lock_mutex_enter_kernel();
/* Note: when we move locks from record to record, waiting locks
and possible granted gap type locks behind them are enqueued in
the original order, because new elements are inserted to a hash
table to the end of the hash chain, and lock_rec_add_to_queue
does not reuse locks if there are waiters in the queue. */
for (lock = lock_rec_get_first_on_page(block); lock;
lock = lock_rec_get_next_on_page(lock)) {
page_cur_t cur1;
page_cur_t cur2;
const ulint type_mode = lock->type_mode;
page_cur_position(rec, block, &cur1);
if (page_cur_is_before_first(&cur1)) {
page_cur_move_to_next(&cur1);
}
page_cur_set_before_first(new_block, &cur2);
page_cur_move_to_next(&cur2);
/* Copy lock requests on user records to new page and
reset the lock bits on the old */
while (!page_cur_is_after_last(&cur1)) {
ulint heap_no;
if (comp) {
heap_no = rec_get_heap_no_new(
page_cur_get_rec(&cur1));
} else {
heap_no = rec_get_heap_no_old(
page_cur_get_rec(&cur1));
ut_ad(!memcmp(page_cur_get_rec(&cur1),
page_cur_get_rec(&cur2),
rec_get_data_size_old(
page_cur_get_rec(&cur2))));
}
if (lock_rec_get_nth_bit(lock, heap_no)) {
lock_rec_reset_nth_bit(lock, heap_no);
if (UNIV_UNLIKELY(type_mode & LOCK_WAIT)) {
lock_reset_lock_and_trx_wait(lock);
}
if (comp) {
heap_no = rec_get_heap_no_new(
page_cur_get_rec(&cur2));
} else {
heap_no = rec_get_heap_no_old(
page_cur_get_rec(&cur2));
}
lock_rec_add_to_queue(type_mode,
new_block, heap_no,
lock->index, lock->trx);
}
page_cur_move_to_next(&cur1);
page_cur_move_to_next(&cur2);
}
}
lock_mutex_exit_kernel();
#ifdef UNIV_DEBUG_LOCK_VALIDATE
ut_ad(lock_rec_validate_page(buf_block_get_space(block),
buf_block_get_zip_size(block),
buf_block_get_page_no(block)));
ut_ad(lock_rec_validate_page(buf_block_get_space(new_block),
buf_block_get_zip_size(block),
buf_block_get_page_no(new_block)));
#endif
}
/*************************************************************//**
Moves the explicit locks on user records to another page if a record
list start is moved to another page. */
UNIV_INTERN
void
lock_move_rec_list_start(
/*=====================*/
const buf_block_t* new_block, /*!< in: index page to move to */
const buf_block_t* block, /*!< in: index page */
const rec_t* rec, /*!< in: record on page:
this is the first
record NOT copied */
const rec_t* old_end) /*!< in: old
previous-to-last
record on new_page
before the records
were copied */
{
lock_t* lock;
const ulint comp = page_rec_is_comp(rec);
ut_ad(block->frame == page_align(rec));
ut_ad(new_block->frame == page_align(old_end));
lock_mutex_enter_kernel();
for (lock = lock_rec_get_first_on_page(block); lock;
lock = lock_rec_get_next_on_page(lock)) {
page_cur_t cur1;
page_cur_t cur2;
const ulint type_mode = lock->type_mode;
page_cur_set_before_first(block, &cur1);
page_cur_move_to_next(&cur1);
page_cur_position(old_end, new_block, &cur2);
page_cur_move_to_next(&cur2);
/* Copy lock requests on user records to new page and
reset the lock bits on the old */
while (page_cur_get_rec(&cur1) != rec) {
ulint heap_no;
if (comp) {
heap_no = rec_get_heap_no_new(
page_cur_get_rec(&cur1));
} else {
heap_no = rec_get_heap_no_old(
page_cur_get_rec(&cur1));
ut_ad(!memcmp(page_cur_get_rec(&cur1),
page_cur_get_rec(&cur2),
rec_get_data_size_old(
page_cur_get_rec(
&cur2))));
}
if (lock_rec_get_nth_bit(lock, heap_no)) {
lock_rec_reset_nth_bit(lock, heap_no);
if (UNIV_UNLIKELY(type_mode & LOCK_WAIT)) {
lock_reset_lock_and_trx_wait(lock);
}
if (comp) {
heap_no = rec_get_heap_no_new(
page_cur_get_rec(&cur2));
} else {
heap_no = rec_get_heap_no_old(
page_cur_get_rec(&cur2));
}
lock_rec_add_to_queue(type_mode,
new_block, heap_no,
lock->index, lock->trx);
}
page_cur_move_to_next(&cur1);
page_cur_move_to_next(&cur2);
}
#ifdef UNIV_DEBUG
if (page_rec_is_supremum(rec)) {
ulint i;
for (i = PAGE_HEAP_NO_USER_LOW;
i < lock_rec_get_n_bits(lock); i++) {
if (UNIV_UNLIKELY
(lock_rec_get_nth_bit(lock, i))) {
fprintf(stderr,
"lock_move_rec_list_start():"
" %lu not moved in %p\n",
(ulong) i, (void*) lock);
ut_error;
}
}
}
#endif /* UNIV_DEBUG */
}
lock_mutex_exit_kernel();
#ifdef UNIV_DEBUG_LOCK_VALIDATE
ut_ad(lock_rec_validate_page(buf_block_get_space(block),
buf_block_get_zip_size(block),
buf_block_get_page_no(block)));
#endif
}
/*************************************************************//**
Updates the lock table when a page is split to the right. */
UNIV_INTERN
void
lock_update_split_right(
/*====================*/
const buf_block_t* right_block, /*!< in: right page */
const buf_block_t* left_block) /*!< in: left page */
{
ulint heap_no = lock_get_min_heap_no(right_block);
lock_mutex_enter_kernel();
/* Move the locks on the supremum of the left page to the supremum
of the right page */
lock_rec_move(right_block, left_block,
PAGE_HEAP_NO_SUPREMUM, PAGE_HEAP_NO_SUPREMUM);
/* Inherit the locks to the supremum of left page from the successor
of the infimum on right page */
lock_rec_inherit_to_gap(left_block, right_block,
PAGE_HEAP_NO_SUPREMUM, heap_no);
lock_mutex_exit_kernel();
}
/*************************************************************//**
Updates the lock table when a page is merged to the right. */
UNIV_INTERN
void
lock_update_merge_right(
/*====================*/
const buf_block_t* right_block, /*!< in: right page to
which merged */
const rec_t* orig_succ, /*!< in: original
successor of infimum
on the right page
before merge */
const buf_block_t* left_block) /*!< in: merged index
page which will be
discarded */
{
lock_mutex_enter_kernel();
/* Inherit the locks from the supremum of the left page to the
original successor of infimum on the right page, to which the left
page was merged */
lock_rec_inherit_to_gap(right_block, left_block,
page_rec_get_heap_no(orig_succ),
PAGE_HEAP_NO_SUPREMUM);
/* Reset the locks on the supremum of the left page, releasing
waiting transactions */
lock_rec_reset_and_release_wait(left_block,
PAGE_HEAP_NO_SUPREMUM);
lock_rec_free_all_from_discard_page(left_block);
lock_mutex_exit_kernel();
}
/*************************************************************//**
Updates the lock table when the root page is copied to another in
btr_root_raise_and_insert. Note that we leave lock structs on the
root page, even though they do not make sense on other than leaf
pages: the reason is that in a pessimistic update the infimum record
of the root page will act as a dummy carrier of the locks of the record
to be updated. */
UNIV_INTERN
void
lock_update_root_raise(
/*===================*/
const buf_block_t* block, /*!< in: index page to which copied */
const buf_block_t* root) /*!< in: root page */
{
lock_mutex_enter_kernel();
/* Move the locks on the supremum of the root to the supremum
of block */
lock_rec_move(block, root,
PAGE_HEAP_NO_SUPREMUM, PAGE_HEAP_NO_SUPREMUM);
lock_mutex_exit_kernel();
}
/*************************************************************//**
Updates the lock table when a page is copied to another and the original page
is removed from the chain of leaf pages, except if page is the root! */
UNIV_INTERN
void
lock_update_copy_and_discard(
/*=========================*/
const buf_block_t* new_block, /*!< in: index page to
which copied */
const buf_block_t* block) /*!< in: index page;
NOT the root! */
{
lock_mutex_enter_kernel();
/* Move the locks on the supremum of the old page to the supremum
of new_page */
lock_rec_move(new_block, block,
PAGE_HEAP_NO_SUPREMUM, PAGE_HEAP_NO_SUPREMUM);
lock_rec_free_all_from_discard_page(block);
lock_mutex_exit_kernel();
}
/*************************************************************//**
Updates the lock table when a page is split to the left. */
UNIV_INTERN
void
lock_update_split_left(
/*===================*/
const buf_block_t* right_block, /*!< in: right page */
const buf_block_t* left_block) /*!< in: left page */
{
ulint heap_no = lock_get_min_heap_no(right_block);
lock_mutex_enter_kernel();
/* Inherit the locks to the supremum of the left page from the
successor of the infimum on the right page */
lock_rec_inherit_to_gap(left_block, right_block,
PAGE_HEAP_NO_SUPREMUM, heap_no);
lock_mutex_exit_kernel();
}
/*************************************************************//**
Updates the lock table when a page is merged to the left. */
UNIV_INTERN
void
lock_update_merge_left(
/*===================*/
const buf_block_t* left_block, /*!< in: left page to
which merged */
const rec_t* orig_pred, /*!< in: original predecessor
of supremum on the left page
before merge */
const buf_block_t* right_block) /*!< in: merged index page
which will be discarded */
{
const rec_t* left_next_rec;
ut_ad(left_block->frame == page_align(orig_pred));
lock_mutex_enter_kernel();
left_next_rec = page_rec_get_next_const(orig_pred);
if (!page_rec_is_supremum(left_next_rec)) {
/* Inherit the locks on the supremum of the left page to the
first record which was moved from the right page */
lock_rec_inherit_to_gap(left_block, left_block,
page_rec_get_heap_no(left_next_rec),
PAGE_HEAP_NO_SUPREMUM);
/* Reset the locks on the supremum of the left page,
releasing waiting transactions */
lock_rec_reset_and_release_wait(left_block,
PAGE_HEAP_NO_SUPREMUM);
}
/* Move the locks from the supremum of right page to the supremum
of the left page */
lock_rec_move(left_block, right_block,
PAGE_HEAP_NO_SUPREMUM, PAGE_HEAP_NO_SUPREMUM);
lock_rec_free_all_from_discard_page(right_block);
lock_mutex_exit_kernel();
}
/*************************************************************//**
Resets the original locks on heir and replaces them with gap type locks
inherited from rec. */
UNIV_INTERN
void
lock_rec_reset_and_inherit_gap_locks(
/*=================================*/
const buf_block_t* heir_block, /*!< in: block containing the
record which inherits */
const buf_block_t* block, /*!< in: block containing the
record from which inherited;
does NOT reset the locks on
this record */
ulint heir_heap_no, /*!< in: heap_no of the
inheriting record */
ulint heap_no) /*!< in: heap_no of the
donating record */
{
mutex_enter(&kernel_mutex);
lock_rec_reset_and_release_wait(heir_block, heir_heap_no);
lock_rec_inherit_to_gap(heir_block, block, heir_heap_no, heap_no);
mutex_exit(&kernel_mutex);
}
/*************************************************************//**
Updates the lock table when a page is discarded. */
UNIV_INTERN
void
lock_update_discard(
/*================*/
const buf_block_t* heir_block, /*!< in: index page
which will inherit the locks */
ulint heir_heap_no, /*!< in: heap_no of the record
which will inherit the locks */
const buf_block_t* block) /*!< in: index page
which will be discarded */
{
const page_t* page = block->frame;
const rec_t* rec;
ulint heap_no;
lock_mutex_enter_kernel();
if (!lock_rec_get_first_on_page(block)) {
/* No locks exist on page, nothing to do */
lock_mutex_exit_kernel();
return;
}
/* Inherit all the locks on the page to the record and reset all
the locks on the page */
if (page_is_comp(page)) {
rec = page + PAGE_NEW_INFIMUM;
do {
heap_no = rec_get_heap_no_new(rec);
lock_rec_inherit_to_gap(heir_block, block,
heir_heap_no, heap_no);
lock_rec_reset_and_release_wait(block, heap_no);
rec = page + rec_get_next_offs(rec, TRUE);
} while (heap_no != PAGE_HEAP_NO_SUPREMUM);
} else {
rec = page + PAGE_OLD_INFIMUM;
do {
heap_no = rec_get_heap_no_old(rec);
lock_rec_inherit_to_gap(heir_block, block,
heir_heap_no, heap_no);
lock_rec_reset_and_release_wait(block, heap_no);
rec = page + rec_get_next_offs(rec, FALSE);
} while (heap_no != PAGE_HEAP_NO_SUPREMUM);
}
lock_rec_free_all_from_discard_page(block);
lock_mutex_exit_kernel();
}
/*************************************************************//**
Updates the lock table when a new user record is inserted. */
UNIV_INTERN
void
lock_update_insert(
/*===============*/
const buf_block_t* block, /*!< in: buffer block containing rec */
const rec_t* rec) /*!< in: the inserted record */
{
ulint receiver_heap_no;
ulint donator_heap_no;
ut_ad(block->frame == page_align(rec));
/* Inherit the gap-locking locks for rec, in gap mode, from the next
record */
if (page_rec_is_comp(rec)) {
receiver_heap_no = rec_get_heap_no_new(rec);
donator_heap_no = rec_get_heap_no_new(
page_rec_get_next_low(rec, TRUE));
} else {
receiver_heap_no = rec_get_heap_no_old(rec);
donator_heap_no = rec_get_heap_no_old(
page_rec_get_next_low(rec, FALSE));
}
lock_mutex_enter_kernel();
lock_rec_inherit_to_gap_if_gap_lock(block,
receiver_heap_no, donator_heap_no);
lock_mutex_exit_kernel();
}
/*************************************************************//**
Updates the lock table when a record is removed. */
UNIV_INTERN
void
lock_update_delete(
/*===============*/
const buf_block_t* block, /*!< in: buffer block containing rec */
const rec_t* rec) /*!< in: the record to be removed */
{
const page_t* page = block->frame;
ulint heap_no;
ulint next_heap_no;
ut_ad(page == page_align(rec));
if (page_is_comp(page)) {
heap_no = rec_get_heap_no_new(rec);
next_heap_no = rec_get_heap_no_new(page
+ rec_get_next_offs(rec,
TRUE));
} else {
heap_no = rec_get_heap_no_old(rec);
next_heap_no = rec_get_heap_no_old(page
+ rec_get_next_offs(rec,
FALSE));
}
lock_mutex_enter_kernel();
/* Let the next record inherit the locks from rec, in gap mode */
lock_rec_inherit_to_gap(block, block, next_heap_no, heap_no);
/* Reset the lock bits on rec and release waiting transactions */
lock_rec_reset_and_release_wait(block, heap_no);
lock_mutex_exit_kernel();
}
/*********************************************************************//**
Stores on the page infimum record the explicit locks of another record.
This function is used to store the lock state of a record when it is
updated and the size of the record changes in the update. The record
is moved in such an update, perhaps to another page. The infimum record
acts as a dummy carrier record, taking care of lock releases while the
actual record is being moved. */
UNIV_INTERN
void
lock_rec_store_on_page_infimum(
/*===========================*/
const buf_block_t* block, /*!< in: buffer block containing rec */
const rec_t* rec) /*!< in: record whose lock state
is stored on the infimum
record of the same page; lock
bits are reset on the
record */
{
ulint heap_no = page_rec_get_heap_no(rec);
ut_ad(block->frame == page_align(rec));
lock_mutex_enter_kernel();
lock_rec_move(block, block, PAGE_HEAP_NO_INFIMUM, heap_no);
lock_mutex_exit_kernel();
}
/*********************************************************************//**
Restores the state of explicit lock requests on a single record, where the
state was stored on the infimum of the page. */
UNIV_INTERN
void
lock_rec_restore_from_page_infimum(
/*===============================*/
const buf_block_t* block, /*!< in: buffer block containing rec */
const rec_t* rec, /*!< in: record whose lock state
is restored */
const buf_block_t* donator)/*!< in: page (rec is not
necessarily on this page)
whose infimum stored the lock
state; lock bits are reset on
the infimum */
{
ulint heap_no = page_rec_get_heap_no(rec);
lock_mutex_enter_kernel();
lock_rec_move(block, donator, heap_no, PAGE_HEAP_NO_INFIMUM);
lock_mutex_exit_kernel();
}
/*=========== DEADLOCK CHECKING ======================================*/
/********************************************************************//**
Checks if a lock request results in a deadlock.
@return TRUE if a deadlock was detected and we chose trx as a victim;
FALSE if no deadlock, or there was a deadlock, but we chose other
transaction(s) as victim(s) */
static
ibool
lock_deadlock_occurs(
/*=================*/
lock_t* lock, /*!< in: lock the transaction is requesting */
trx_t* trx) /*!< in: transaction */
{
trx_t* mark_trx;
ulint ret;
ulint cost = 0;
ut_ad(trx);
ut_ad(lock);
ut_ad(mutex_own(&kernel_mutex));
retry:
/* We check that adding this trx to the waits-for graph
does not produce a cycle. First mark all active transactions
with 0: */
mark_trx = UT_LIST_GET_FIRST(trx_sys->trx_list);
while (mark_trx) {
mark_trx->deadlock_mark = 0;
mark_trx = UT_LIST_GET_NEXT(trx_list, mark_trx);
}
ret = lock_deadlock_recursive(trx, trx, lock, &cost, 0);
switch (ret) {
case LOCK_VICTIM_IS_OTHER:
/* We chose some other trx as a victim: retry if there still
is a deadlock */
goto retry;
case LOCK_EXCEED_MAX_DEPTH:
/* If the lock search exceeds the max step
or the max depth, the current trx will be
the victim. Print its information. */
rewind(lock_latest_err_file);
ut_print_timestamp(lock_latest_err_file);
fputs("TOO DEEP OR LONG SEARCH IN THE LOCK TABLE"
" WAITS-FOR GRAPH, WE WILL ROLL BACK"
" FOLLOWING TRANSACTION \n",
lock_latest_err_file);
fputs("\n*** TRANSACTION:\n", lock_latest_err_file);
trx_print(lock_latest_err_file, trx, 3000);
fputs("*** WAITING FOR THIS LOCK TO BE GRANTED:\n",
lock_latest_err_file);
if (lock_get_type(lock) == LOCK_REC) {
lock_rec_print(lock_latest_err_file, lock);
} else {
lock_table_print(lock_latest_err_file, lock);
}
break;
case LOCK_VICTIM_IS_START:
srv_n_lock_deadlock_count++;
fputs("*** WE ROLL BACK TRANSACTION (2)\n",
lock_latest_err_file);
break;
default:
/* No deadlock detected*/
return(FALSE);
}
lock_deadlock_found = TRUE;
return(TRUE);
}
/********************************************************************//**
Looks recursively for a deadlock.
@return 0 if no deadlock found, LOCK_VICTIM_IS_START if there was a
deadlock and we chose 'start' as the victim, LOCK_VICTIM_IS_OTHER if a
deadlock was found and we chose some other trx as a victim: we must do
the search again in this last case because there may be another
deadlock!
LOCK_EXCEED_MAX_DEPTH if the lock search exceeds max steps or max depth. */
static
ulint
lock_deadlock_recursive(
/*====================*/
trx_t* start, /*!< in: recursion starting point */
trx_t* trx, /*!< in: a transaction waiting for a lock */
lock_t* wait_lock, /*!< in: lock that is waiting to be granted */
ulint* cost, /*!< in/out: number of calculation steps thus
far: if this exceeds LOCK_MAX_N_STEPS_...
we return LOCK_EXCEED_MAX_DEPTH */
ulint depth) /*!< in: recursion depth: if this exceeds
LOCK_MAX_DEPTH_IN_DEADLOCK_CHECK, we
return LOCK_EXCEED_MAX_DEPTH */
{
ulint ret;
lock_t* lock;
trx_t* lock_trx;
ulint heap_no = ULINT_UNDEFINED;
ut_a(trx);
ut_a(start);
ut_a(wait_lock);
ut_ad(mutex_own(&kernel_mutex));
if (trx->deadlock_mark == 1) {
/* We have already exhaustively searched the subtree starting
from this trx */
return(0);
}
*cost = *cost + 1;
if (lock_get_type_low(wait_lock) == LOCK_REC) {
ulint space;
ulint page_no;
heap_no = lock_rec_find_set_bit(wait_lock);
ut_a(heap_no != ULINT_UNDEFINED);
space = wait_lock->un_member.rec_lock.space;
page_no = wait_lock->un_member.rec_lock.page_no;
lock = lock_rec_get_first_on_page_addr(space, page_no);
/* Position the iterator on the first matching record lock. */
while (lock != NULL
&& lock != wait_lock
&& !lock_rec_get_nth_bit(lock, heap_no)) {
lock = lock_rec_get_next_on_page(lock);
}
if (lock == wait_lock) {
lock = NULL;
}
ut_ad(lock == NULL || lock_rec_get_nth_bit(lock, heap_no));
} else {
lock = wait_lock;
}
/* Look at the locks ahead of wait_lock in the lock queue */
for (;;) {
/* Get previous table lock. */
if (heap_no == ULINT_UNDEFINED) {
lock = UT_LIST_GET_PREV(
un_member.tab_lock.locks, lock);
}
if (lock == NULL) {
/* We can mark this subtree as searched */
trx->deadlock_mark = 1;
return(FALSE);
}
if (lock_has_to_wait(wait_lock, lock)) {
ibool too_far
= depth > LOCK_MAX_DEPTH_IN_DEADLOCK_CHECK
|| *cost > LOCK_MAX_N_STEPS_IN_DEADLOCK_CHECK;
lock_trx = lock->trx;
if (lock_trx == start) {
/* We came back to the recursion starting
point: a deadlock detected; or we have
searched the waits-for graph too long */
FILE* ef = lock_latest_err_file;
rewind(ef);
ut_print_timestamp(ef);
fputs("\n*** (1) TRANSACTION:\n", ef);
trx_print(ef, wait_lock->trx, 3000);
fputs("*** (1) WAITING FOR THIS LOCK"
" TO BE GRANTED:\n", ef);
if (lock_get_type_low(wait_lock) == LOCK_REC) {
lock_rec_print(ef, wait_lock);
} else {
lock_table_print(ef, wait_lock);
}
fputs("*** (2) TRANSACTION:\n", ef);
trx_print(ef, lock->trx, 3000);
fputs("*** (2) HOLDS THE LOCK(S):\n", ef);
if (lock_get_type_low(lock) == LOCK_REC) {
lock_rec_print(ef, lock);
} else {
lock_table_print(ef, lock);
}
fputs("*** (2) WAITING FOR THIS LOCK"
" TO BE GRANTED:\n", ef);
if (lock_get_type_low(start->wait_lock)
== LOCK_REC) {
lock_rec_print(ef, start->wait_lock);
} else {
lock_table_print(ef, start->wait_lock);
}
#ifdef UNIV_DEBUG
if (lock_print_waits) {
fputs("Deadlock detected\n",
stderr);
}
#endif /* UNIV_DEBUG */
if (trx_weight_cmp(wait_lock->trx,
start) >= 0) {
/* Our recursion starting point
transaction is 'smaller', let us
choose 'start' as the victim and roll
back it */
return(LOCK_VICTIM_IS_START);
}
lock_deadlock_found = TRUE;
/* Let us choose the transaction of wait_lock
as a victim to try to avoid deadlocking our
recursion starting point transaction */
fputs("*** WE ROLL BACK TRANSACTION (1)\n",
ef);
wait_lock->trx->was_chosen_as_deadlock_victim
= TRUE;
lock_cancel_waiting_and_release(wait_lock);
/* Since trx and wait_lock are no longer
in the waits-for graph, we can return FALSE;
note that our selective algorithm can choose
several transactions as victims, but still
we may end up rolling back also the recursion
starting point transaction! */
return(LOCK_VICTIM_IS_OTHER);
}
if (too_far) {
#ifdef UNIV_DEBUG
if (lock_print_waits) {
fputs("Deadlock search exceeds"
" max steps or depth.\n",
stderr);
}
#endif /* UNIV_DEBUG */
/* The information about transaction/lock
to be rolled back is available in the top
level. Do not print anything here. */
return(LOCK_EXCEED_MAX_DEPTH);
}
if (lock_trx->que_state == TRX_QUE_LOCK_WAIT) {
/* Another trx ahead has requested lock in an
incompatible mode, and is itself waiting for
a lock */
ret = lock_deadlock_recursive(
start, lock_trx,
lock_trx->wait_lock, cost, depth + 1);
if (ret != 0) {
return(ret);
}
}
}
/* Get the next record lock to check. */
if (heap_no != ULINT_UNDEFINED) {
ut_a(lock != NULL);
do {
lock = lock_rec_get_next_on_page(lock);
} while (lock != NULL
&& lock != wait_lock
&& !lock_rec_get_nth_bit(lock, heap_no));
if (lock == wait_lock) {
lock = NULL;
}
}
}/* end of the 'for (;;)'-loop */
}
/*========================= TABLE LOCKS ==============================*/
/*********************************************************************//**
Creates a table lock object and adds it as the last in the lock queue
of the table. Does NOT check for deadlocks or lock compatibility.
@return own: new lock object */
UNIV_INLINE
lock_t*
lock_table_create(
/*==============*/
dict_table_t* table, /*!< in: database table in dictionary cache */
ulint type_mode,/*!< in: lock mode possibly ORed with
LOCK_WAIT */
trx_t* trx) /*!< in: trx */
{
lock_t* lock;
ut_ad(table && trx);
ut_ad(mutex_own(&kernel_mutex));
if ((type_mode & LOCK_MODE_MASK) == LOCK_AUTO_INC) {
++table->n_waiting_or_granted_auto_inc_locks;
}
/* For AUTOINC locking we reuse the lock instance only if
there is no wait involved else we allocate the waiting lock
from the transaction lock heap. */
if (type_mode == LOCK_AUTO_INC) {
lock = table->autoinc_lock;
table->autoinc_trx = trx;
ib_vector_push(trx->autoinc_locks, lock);
} else {
lock = mem_heap_alloc(trx->lock_heap, sizeof(lock_t));
}
UT_LIST_ADD_LAST(trx_locks, trx->trx_locks, lock);
lock->type_mode = type_mode | LOCK_TABLE;
lock->trx = trx;
lock->un_member.tab_lock.table = table;
UT_LIST_ADD_LAST(un_member.tab_lock.locks, table->locks, lock);
if (UNIV_UNLIKELY(type_mode & LOCK_WAIT)) {
lock_set_lock_and_trx_wait(lock, trx);
}
return(lock);
}
/*************************************************************//**
Removes a table lock request from the queue and the trx list of locks;
this is a low-level function which does NOT check if waiting requests
can now be granted. */
UNIV_INLINE
void
lock_table_remove_low(
/*==================*/
lock_t* lock) /*!< in: table lock */
{
trx_t* trx;
dict_table_t* table;
ut_ad(mutex_own(&kernel_mutex));
trx = lock->trx;
table = lock->un_member.tab_lock.table;
/* Remove the table from the transaction's AUTOINC vector, if
the lock that is being release is an AUTOINC lock. */
if (lock_get_mode(lock) == LOCK_AUTO_INC) {
/* The table's AUTOINC lock can get transferred to
another transaction before we get here. */
if (table->autoinc_trx == trx) {
table->autoinc_trx = NULL;
}
/* The locks must be freed in the reverse order from
the one in which they were acquired. This is to avoid
traversing the AUTOINC lock vector unnecessarily.
We only store locks that were granted in the
trx->autoinc_locks vector (see lock_table_create()
and lock_grant()). Therefore it can be empty and we
need to check for that. */
if (!lock_get_wait(lock)
&& !ib_vector_is_empty(trx->autoinc_locks)) {
lock_t* autoinc_lock;
autoinc_lock = ib_vector_pop(trx->autoinc_locks);
ut_a(autoinc_lock == lock);
}
ut_a(table->n_waiting_or_granted_auto_inc_locks > 0);
--table->n_waiting_or_granted_auto_inc_locks;
}
UT_LIST_REMOVE(trx_locks, trx->trx_locks, lock);
UT_LIST_REMOVE(un_member.tab_lock.locks, table->locks, lock);
}
/*********************************************************************//**
Enqueues a waiting request for a table lock which cannot be granted
immediately. Checks for deadlocks.
@return DB_LOCK_WAIT, DB_DEADLOCK, or DB_QUE_THR_SUSPENDED, or
DB_SUCCESS; DB_SUCCESS means that there was a deadlock, but another
transaction was chosen as a victim, and we got the lock immediately:
no need to wait then */
static
ulint
lock_table_enqueue_waiting(
/*=======================*/
ulint mode, /*!< in: lock mode this transaction is
requesting */
dict_table_t* table, /*!< in: table */
que_thr_t* thr) /*!< in: query thread */
{
lock_t* lock;
trx_t* trx;
ulint sec;
ulint ms;
ut_ad(mutex_own(&kernel_mutex));
/* Test if there already is some other reason to suspend thread:
we do not enqueue a lock request if the query thread should be
stopped anyway */
if (que_thr_stop(thr)) {
ut_error;
return(DB_QUE_THR_SUSPENDED);
}
trx = thr_get_trx(thr);
switch (trx_get_dict_operation(trx)) {
case TRX_DICT_OP_NONE:
break;
case TRX_DICT_OP_TABLE:
case TRX_DICT_OP_INDEX:
ut_print_timestamp(stderr);
fputs(" InnoDB: Error: a table lock wait happens"
" in a dictionary operation!\n"
"InnoDB: Table name ", stderr);
ut_print_name(stderr, trx, TRUE, table->name);
fputs(".\n"
"InnoDB: Submit a detailed bug report"
" to http://bugs.mysql.com\n",
stderr);
}
/* Enqueue the lock request that will wait to be granted */
lock = lock_table_create(table, mode | LOCK_WAIT, trx);
/* Check if a deadlock occurs: if yes, remove the lock request and
return an error code */
if (lock_deadlock_occurs(lock, trx)) {
/* The order here is important, we don't want to
lose the state of the lock before calling remove. */
lock_table_remove_low(lock);
lock_reset_lock_and_trx_wait(lock);
return(DB_DEADLOCK);
}
if (trx->wait_lock == NULL) {
/* Deadlock resolution chose another transaction as a victim,
and we accidentally got our lock granted! */
return(DB_SUCCESS);
}
if (innobase_get_slow_log() && trx->take_stats) {
ut_usectime(&sec, &ms);
trx->lock_que_wait_ustarted = (ib_uint64_t)sec * 1000000 + ms;
}
trx->que_state = TRX_QUE_LOCK_WAIT;
trx->was_chosen_as_deadlock_victim = FALSE;
trx->wait_started = time(NULL);
ut_a(que_thr_stop(thr));
return(DB_LOCK_WAIT);
}
/*********************************************************************//**
Checks if other transactions have an incompatible mode lock request in
the lock queue.
@return lock or NULL */
UNIV_INLINE
lock_t*
lock_table_other_has_incompatible(
/*==============================*/
trx_t* trx, /*!< in: transaction, or NULL if all
transactions should be included */
ulint wait, /*!< in: LOCK_WAIT if also waiting locks are
taken into account, or 0 if not */
dict_table_t* table, /*!< in: table */
enum lock_mode mode) /*!< in: lock mode */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
lock = UT_LIST_GET_LAST(table->locks);
while (lock != NULL) {
if ((lock->trx != trx)
&& (!lock_mode_compatible(lock_get_mode(lock), mode))
&& (wait || !(lock_get_wait(lock)))) {
return(lock);
}
lock = UT_LIST_GET_PREV(un_member.tab_lock.locks, lock);
}
return(NULL);
}
/*********************************************************************//**
Locks the specified database table in the mode given. If the lock cannot
be granted immediately, the query thread is put to wait.
@return DB_SUCCESS, DB_LOCK_WAIT, DB_DEADLOCK, or DB_QUE_THR_SUSPENDED */
UNIV_INTERN
ulint
lock_table(
/*=======*/
ulint flags, /*!< in: if BTR_NO_LOCKING_FLAG bit is set,
does nothing */
dict_table_t* table, /*!< in: database table in dictionary cache */
enum lock_mode mode, /*!< in: lock mode */
que_thr_t* thr) /*!< in: query thread */
{
trx_t* trx;
ulint err;
ut_ad(table && thr);
if (flags & BTR_NO_LOCKING_FLAG) {
return(DB_SUCCESS);
}
ut_a(flags == 0);
trx = thr_get_trx(thr);
lock_mutex_enter_kernel();
/* Look for stronger locks the same trx already has on the table */
if (lock_table_has(trx, table, mode)) {
lock_mutex_exit_kernel();
return(DB_SUCCESS);
}
/* We have to check if the new lock is compatible with any locks
other transactions have in the table lock queue. */
if (lock_table_other_has_incompatible(trx, LOCK_WAIT, table, mode)) {
/* Another trx has a request on the table in an incompatible
mode: this trx may have to wait */
err = lock_table_enqueue_waiting(mode | flags, table, thr);
lock_mutex_exit_kernel();
return(err);
}
lock_table_create(table, mode | flags, trx);
ut_a(!flags || mode == LOCK_S || mode == LOCK_X);
lock_mutex_exit_kernel();
return(DB_SUCCESS);
}
/*********************************************************************//**
Checks if a waiting table lock request still has to wait in a queue.
@return TRUE if still has to wait */
static
ibool
lock_table_has_to_wait_in_queue(
/*============================*/
lock_t* wait_lock) /*!< in: waiting table lock */
{
dict_table_t* table;
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
ut_ad(lock_get_wait(wait_lock));
table = wait_lock->un_member.tab_lock.table;
lock = UT_LIST_GET_FIRST(table->locks);
while (lock != wait_lock) {
if (lock_has_to_wait(wait_lock, lock)) {
return(TRUE);
}
lock = UT_LIST_GET_NEXT(un_member.tab_lock.locks, lock);
}
return(FALSE);
}
/*************************************************************//**
Removes a table lock request, waiting or granted, from the queue and grants
locks to other transactions in the queue, if they now are entitled to a
lock. */
static
void
lock_table_dequeue(
/*===============*/
lock_t* in_lock)/*!< in: table lock object; transactions waiting
behind will get their lock requests granted, if
they are now qualified to it */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
ut_a(lock_get_type_low(in_lock) == LOCK_TABLE);
lock = UT_LIST_GET_NEXT(un_member.tab_lock.locks, in_lock);
lock_table_remove_low(in_lock);
/* Check if waiting locks in the queue can now be granted: grant
locks if there are no conflicting locks ahead. */
while (lock != NULL) {
if (lock_get_wait(lock)
&& !lock_table_has_to_wait_in_queue(lock)) {
/* Grant the lock */
lock_grant(lock);
}
lock = UT_LIST_GET_NEXT(un_member.tab_lock.locks, lock);
}
}
/*=========================== LOCK RELEASE ==============================*/
/*************************************************************//**
Removes a granted record lock of a transaction from the queue and grants
locks to other transactions waiting in the queue if they now are entitled
to a lock. */
UNIV_INTERN
void
lock_rec_unlock(
/*============*/
trx_t* trx, /*!< in: transaction that has
set a record lock */
const buf_block_t* block, /*!< in: buffer block containing rec */
const rec_t* rec, /*!< in: record */
enum lock_mode lock_mode)/*!< in: LOCK_S or LOCK_X */
{
lock_t* first_lock;
lock_t* lock;
ulint heap_no;
ut_ad(trx && rec);
ut_ad(block->frame == page_align(rec));
heap_no = page_rec_get_heap_no(rec);
mutex_enter(&kernel_mutex);
first_lock = lock_rec_get_first(block, heap_no);
/* Find the last lock with the same lock_mode and transaction
from the record. */
for (lock = first_lock; lock != NULL;
lock = lock_rec_get_next(heap_no, lock)) {
if (lock->trx == trx && lock_get_mode(lock) == lock_mode) {
ut_a(!lock_get_wait(lock));
lock_rec_reset_nth_bit(lock, heap_no);
goto released;
}
}
mutex_exit(&kernel_mutex);
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Error: unlock row could not"
" find a %lu mode lock on the record\n",
(ulong) lock_mode);
return;
released:
/* Check if we can now grant waiting lock requests */
for (lock = first_lock; lock != NULL;
lock = lock_rec_get_next(heap_no, lock)) {
if (lock_get_wait(lock)
&& !lock_rec_has_to_wait_in_queue(lock)) {
/* Grant the lock */
lock_grant(lock);
}
}
mutex_exit(&kernel_mutex);
}
/*********************************************************************//**
Releases transaction locks, and releases possible other transactions waiting
because of these locks. */
UNIV_INTERN
void
lock_release_off_kernel(
/*====================*/
trx_t* trx) /*!< in: transaction */
{
dict_table_t* table;
ulint count;
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
lock = UT_LIST_GET_LAST(trx->trx_locks);
count = 0;
while (lock != NULL) {
count++;
if (lock_get_type_low(lock) == LOCK_REC) {
lock_rec_dequeue_from_page(lock);
} else {
ut_ad(lock_get_type_low(lock) & LOCK_TABLE);
if (lock_get_mode(lock) != LOCK_IS
&& !ut_dulint_is_zero(trx->undo_no)) {
/* The trx may have modified the table. We
block the use of the MySQL query cache for
all currently active transactions. */
table = lock->un_member.tab_lock.table;
table->query_cache_inv_trx_id
= trx_sys->max_trx_id;
}
lock_table_dequeue(lock);
}
if (count == LOCK_RELEASE_KERNEL_INTERVAL) {
/* Release the kernel mutex for a while, so that we
do not monopolize it */
lock_mutex_exit_kernel();
lock_mutex_enter_kernel();
count = 0;
}
lock = UT_LIST_GET_LAST(trx->trx_locks);
}
ut_a(ib_vector_size(trx->autoinc_locks) == 0);
mem_heap_empty(trx->lock_heap);
}
/*********************************************************************//**
Cancels a waiting lock request and releases possible other transactions
waiting behind it. */
UNIV_INTERN
void
lock_cancel_waiting_and_release(
/*============================*/
lock_t* lock) /*!< in: waiting lock request */
{
ut_ad(mutex_own(&kernel_mutex));
if (lock_get_type_low(lock) == LOCK_REC) {
lock_rec_dequeue_from_page(lock);
} else {
ut_ad(lock_get_type_low(lock) & LOCK_TABLE);
if (lock->trx->autoinc_locks != NULL) {
/* Release the transaction's AUTOINC locks/ */
lock_release_autoinc_locks(lock->trx);
}
lock_table_dequeue(lock);
}
/* Reset the wait flag and the back pointer to lock in trx */
lock_reset_lock_and_trx_wait(lock);
/* The following function releases the trx from lock wait */
trx_end_lock_wait(lock->trx);
}
/* True if a lock mode is S or X */
#define IS_LOCK_S_OR_X(lock) \
(lock_get_mode(lock) == LOCK_S \
|| lock_get_mode(lock) == LOCK_X)
/*********************************************************************//**
Removes locks of a transaction on a table to be dropped.
If remove_also_table_sx_locks is TRUE then table-level S and X locks are
also removed in addition to other table-level and record-level locks.
No lock, that is going to be removed, is allowed to be a wait lock. */
static
void
lock_remove_all_on_table_for_trx(
/*=============================*/
dict_table_t* table, /*!< in: table to be dropped */
trx_t* trx, /*!< in: a transaction */
ibool remove_also_table_sx_locks)/*!< in: also removes
table S and X locks */
{
lock_t* lock;
lock_t* prev_lock;
ut_ad(mutex_own(&kernel_mutex));
lock = UT_LIST_GET_LAST(trx->trx_locks);
while (lock != NULL) {
prev_lock = UT_LIST_GET_PREV(trx_locks, lock);
if (lock_get_type_low(lock) == LOCK_REC
&& lock->index->table == table) {
ut_a(!lock_get_wait(lock));
lock_rec_discard(lock);
} else if (lock_get_type_low(lock) & LOCK_TABLE
&& lock->un_member.tab_lock.table == table
&& (remove_also_table_sx_locks
|| !IS_LOCK_S_OR_X(lock))) {
ut_a(!lock_get_wait(lock));
lock_table_remove_low(lock);
}
lock = prev_lock;
}
}
/*********************************************************************//**
Removes locks on a table to be dropped or truncated.
If remove_also_table_sx_locks is TRUE then table-level S and X locks are
also removed in addition to other table-level and record-level locks.
No lock, that is going to be removed, is allowed to be a wait lock. */
UNIV_INTERN
void
lock_remove_all_on_table(
/*=====================*/
dict_table_t* table, /*!< in: table to be dropped
or truncated */
ibool remove_also_table_sx_locks)/*!< in: also removes
table S and X locks */
{
lock_t* lock;
lock_t* prev_lock;
mutex_enter(&kernel_mutex);
lock = UT_LIST_GET_FIRST(table->locks);
while (lock != NULL) {
prev_lock = UT_LIST_GET_PREV(un_member.tab_lock.locks,
lock);
/* If we should remove all locks (remove_also_table_sx_locks
is TRUE), or if the lock is not table-level S or X lock,
then check we are not going to remove a wait lock. */
if (remove_also_table_sx_locks
|| !(lock_get_type(lock) == LOCK_TABLE
&& IS_LOCK_S_OR_X(lock))) {
ut_a(!lock_get_wait(lock));
}
lock_remove_all_on_table_for_trx(table, lock->trx,
remove_also_table_sx_locks);
if (prev_lock == NULL) {
if (lock == UT_LIST_GET_FIRST(table->locks)) {
/* lock was not removed, pick its successor */
lock = UT_LIST_GET_NEXT(
un_member.tab_lock.locks, lock);
} else {
/* lock was removed, pick the first one */
lock = UT_LIST_GET_FIRST(table->locks);
}
} else if (UT_LIST_GET_NEXT(un_member.tab_lock.locks,
prev_lock) != lock) {
/* If lock was removed by
lock_remove_all_on_table_for_trx() then pick the
successor of prev_lock ... */
lock = UT_LIST_GET_NEXT(
un_member.tab_lock.locks, prev_lock);
} else {
/* ... otherwise pick the successor of lock. */
lock = UT_LIST_GET_NEXT(
un_member.tab_lock.locks, lock);
}
}
mutex_exit(&kernel_mutex);
}
/*===================== VALIDATION AND DEBUGGING ====================*/
/*********************************************************************//**
Prints info of a table lock. */
UNIV_INTERN
void
lock_table_print(
/*=============*/
FILE* file, /*!< in: file where to print */
const lock_t* lock) /*!< in: table type lock */
{
ut_ad(mutex_own(&kernel_mutex));
ut_a(lock_get_type_low(lock) == LOCK_TABLE);
fputs("TABLE LOCK table ", file);
ut_print_name(file, lock->trx, TRUE,
lock->un_member.tab_lock.table->name);
fprintf(file, " trx id " TRX_ID_FMT,
TRX_ID_PREP_PRINTF(lock->trx->id));
if (lock_get_mode(lock) == LOCK_S) {
fputs(" lock mode S", file);
} else if (lock_get_mode(lock) == LOCK_X) {
fputs(" lock mode X", file);
} else if (lock_get_mode(lock) == LOCK_IS) {
fputs(" lock mode IS", file);
} else if (lock_get_mode(lock) == LOCK_IX) {
fputs(" lock mode IX", file);
} else if (lock_get_mode(lock) == LOCK_AUTO_INC) {
fputs(" lock mode AUTO-INC", file);
} else {
fprintf(file, " unknown lock mode %lu",
(ulong) lock_get_mode(lock));
}
if (lock_get_wait(lock)) {
fputs(" waiting", file);
}
putc('\n', file);
}
/*********************************************************************//**
Prints info of a record lock. */
UNIV_INTERN
void
lock_rec_print(
/*===========*/
FILE* file, /*!< in: file where to print */
const lock_t* lock) /*!< in: record type lock */
{
const buf_block_t* block;
ulint space;
ulint page_no;
ulint i;
mtr_t mtr;
mem_heap_t* heap = NULL;
ulint offsets_[REC_OFFS_NORMAL_SIZE];
ulint* offsets = offsets_;
rec_offs_init(offsets_);
ut_ad(mutex_own(&kernel_mutex));
ut_a(lock_get_type_low(lock) == LOCK_REC);
space = lock->un_member.rec_lock.space;
page_no = lock->un_member.rec_lock.page_no;
fprintf(file, "RECORD LOCKS space id %lu page no %lu n bits %lu ",
(ulong) space, (ulong) page_no,
(ulong) lock_rec_get_n_bits(lock));
dict_index_name_print(file, lock->trx, lock->index);
fprintf(file, " trx id " TRX_ID_FMT,
TRX_ID_PREP_PRINTF(lock->trx->id));
if (lock_get_mode(lock) == LOCK_S) {
fputs(" lock mode S", file);
} else if (lock_get_mode(lock) == LOCK_X) {
fputs(" lock_mode X", file);
} else {
ut_error;
}
if (lock_rec_get_gap(lock)) {
fputs(" locks gap before rec", file);
}
if (lock_rec_get_rec_not_gap(lock)) {
fputs(" locks rec but not gap", file);
}
if (lock_rec_get_insert_intention(lock)) {
fputs(" insert intention", file);
}
if (lock_get_wait(lock)) {
fputs(" waiting", file);
}
mtr_start(&mtr);
putc('\n', file);
if ( srv_show_verbose_locks ) {
block = buf_page_try_get(space, page_no, &mtr);
for (i = 0; i < lock_rec_get_n_bits(lock); ++i) {
if (!lock_rec_get_nth_bit(lock, i)) {
continue;
}
fprintf(file, "Record lock, heap no %lu", (ulong) i);
if (block) {
const rec_t* rec;
rec = page_find_rec_with_heap_no(
buf_block_get_frame(block), i);
offsets = rec_get_offsets(
rec, lock->index, offsets,
ULINT_UNDEFINED, &heap);
putc(' ', file);
rec_print_new(file, rec, offsets);
}
putc('\n', file);
}
}
mtr_commit(&mtr);
if (UNIV_LIKELY_NULL(heap)) {
mem_heap_free(heap);
}
}
#ifdef UNIV_DEBUG
/* Print the number of lock structs from lock_print_info_summary() only
in non-production builds for performance reasons, see
http://bugs.mysql.com/36942 */
#define PRINT_NUM_OF_LOCK_STRUCTS
#endif /* UNIV_DEBUG */
#ifdef PRINT_NUM_OF_LOCK_STRUCTS
/*********************************************************************//**
Calculates the number of record lock structs in the record lock hash table.
@return number of record locks */
static
ulint
lock_get_n_rec_locks(void)
/*======================*/
{
lock_t* lock;
ulint n_locks = 0;
ulint i;
ut_ad(mutex_own(&kernel_mutex));
for (i = 0; i < hash_get_n_cells(lock_sys->rec_hash); i++) {
lock = HASH_GET_FIRST(lock_sys->rec_hash, i);
while (lock) {
n_locks++;
lock = HASH_GET_NEXT(hash, lock);
}
}
return(n_locks);
}
#endif /* PRINT_NUM_OF_LOCK_STRUCTS */
/*********************************************************************//**
Prints info of locks for all transactions.
@return FALSE if not able to obtain kernel mutex
and exits without printing info */
UNIV_INTERN
ibool
lock_print_info_summary(
/*====================*/
FILE* file, /*!< in: file where to print */
ibool nowait) /*!< in: whether to wait for the kernel mutex */
{
/* if nowait is FALSE, wait on the kernel mutex,
otherwise return immediately if fail to obtain the
mutex. */
if (!nowait) {
lock_mutex_enter_kernel();
} else if (mutex_enter_nowait(&kernel_mutex)) {
fputs("FAIL TO OBTAIN KERNEL MUTEX, "
"SKIP LOCK INFO PRINTING\n", file);
return(FALSE);
}
if (lock_deadlock_found) {
fputs("------------------------\n"
"LATEST DETECTED DEADLOCK\n"
"------------------------\n", file);
ut_copy_file(file, lock_latest_err_file);
}
fputs("------------\n"
"TRANSACTIONS\n"
"------------\n", file);
fprintf(file, "Trx id counter " TRX_ID_FMT "\n",
TRX_ID_PREP_PRINTF(trx_sys->max_trx_id));
fprintf(file,
"Purge done for trx's n:o < " TRX_ID_FMT
" undo n:o < " TRX_ID_FMT "\n",
TRX_ID_PREP_PRINTF(purge_sys->purge_trx_no),
TRX_ID_PREP_PRINTF(purge_sys->purge_undo_no));
fprintf(file,
"History list length %lu\n",
(ulong) trx_sys->rseg_history_len);
#ifdef PRINT_NUM_OF_LOCK_STRUCTS
fprintf(file,
"Total number of lock structs in row lock hash table %lu\n",
(ulong) lock_get_n_rec_locks());
#endif /* PRINT_NUM_OF_LOCK_STRUCTS */
return(TRUE);
}
/*********************************************************************//**
Prints info of locks for each transaction. */
UNIV_INTERN
void
lock_print_info_all_transactions(
/*=============================*/
FILE* file) /*!< in: file where to print */
{
lock_t* lock;
ibool load_page_first = TRUE;
ulint nth_trx = 0;
ulint nth_lock = 0;
ulint i;
mtr_t mtr;
trx_t* trx;
fprintf(file, "LIST OF TRANSACTIONS FOR EACH SESSION:\n");
/* First print info on non-active transactions */
trx = UT_LIST_GET_FIRST(trx_sys->mysql_trx_list);
while (trx) {
if (trx->conc_state == TRX_NOT_STARTED) {
fputs("---", file);
trx_print(file, trx, 600);
}
trx = UT_LIST_GET_NEXT(mysql_trx_list, trx);
}
loop:
trx = UT_LIST_GET_FIRST(trx_sys->trx_list);
i = 0;
/* Since we temporarily release the kernel mutex when
reading a database page in below, variable trx may be
obsolete now and we must loop through the trx list to
get probably the same trx, or some other trx. */
while (trx && (i < nth_trx)) {
trx = UT_LIST_GET_NEXT(trx_list, trx);
i++;
}
if (trx == NULL) {
lock_mutex_exit_kernel();
ut_ad(lock_validate());
return;
}
if (nth_lock == 0) {
fputs("---", file);
trx_print(file, trx, 600);
if (trx->read_view) {
fprintf(file,
"Trx read view will not see trx with"
" id >= " TRX_ID_FMT
", sees < " TRX_ID_FMT "\n",
TRX_ID_PREP_PRINTF(
trx->read_view->low_limit_id),
TRX_ID_PREP_PRINTF(
trx->read_view->up_limit_id));
}
if (trx->que_state == TRX_QUE_LOCK_WAIT) {
fprintf(file,
"------- TRX HAS BEEN WAITING %lu SEC"
" FOR THIS LOCK TO BE GRANTED:\n",
(ulong) difftime(time(NULL),
trx->wait_started));
if (lock_get_type_low(trx->wait_lock) == LOCK_REC) {
lock_rec_print(file, trx->wait_lock);
} else {
lock_table_print(file, trx->wait_lock);
}
fputs("------------------\n", file);
}
}
if (!srv_print_innodb_lock_monitor && !srv_show_locks_held) {
nth_trx++;
goto loop;
}
i = 0;
/* Look at the note about the trx loop above why we loop here:
lock may be an obsolete pointer now. */
lock = UT_LIST_GET_FIRST(trx->trx_locks);
while (lock && (i < nth_lock)) {
lock = UT_LIST_GET_NEXT(trx_locks, lock);
i++;
}
if (lock == NULL) {
nth_trx++;
nth_lock = 0;
goto loop;
}
if (lock_get_type_low(lock) == LOCK_REC) {
if (load_page_first) {
ulint space = lock->un_member.rec_lock.space;
ulint zip_size= fil_space_get_zip_size(space);
ulint page_no = lock->un_member.rec_lock.page_no;
if (UNIV_UNLIKELY(zip_size == ULINT_UNDEFINED)) {
/* It is a single table tablespace and
the .ibd file is missing (TRUNCATE
TABLE probably stole the locks): just
print the lock without attempting to
load the page in the buffer pool. */
fprintf(file, "RECORD LOCKS on"
" non-existing space %lu\n",
(ulong) space);
goto print_rec;
}
lock_mutex_exit_kernel();
mtr_start(&mtr);
buf_page_get_with_no_latch(space, zip_size,
page_no, &mtr);
mtr_commit(&mtr);
load_page_first = FALSE;
lock_mutex_enter_kernel();
goto loop;
}
print_rec:
lock_rec_print(file, lock);
} else {
ut_ad(lock_get_type_low(lock) & LOCK_TABLE);
lock_table_print(file, lock);
}
load_page_first = TRUE;
nth_lock++;
if (nth_lock >= srv_show_locks_held) {
fputs("TOO LOCKS PRINTED FOR THIS TRX:"
" SUPPRESSING FURTHER PRINTS\n",
file);
nth_trx++;
nth_lock = 0;
goto loop;
}
goto loop;
}
#ifdef UNIV_DEBUG
/*********************************************************************//**
Validates the lock queue on a table.
@return TRUE if ok */
static
ibool
lock_table_queue_validate(
/*======================*/
dict_table_t* table) /*!< in: table */
{
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
lock = UT_LIST_GET_FIRST(table->locks);
while (lock) {
ut_a(((lock->trx)->conc_state == TRX_ACTIVE)
|| ((lock->trx)->conc_state == TRX_PREPARED)
|| ((lock->trx)->conc_state == TRX_COMMITTED_IN_MEMORY));
if (!lock_get_wait(lock)) {
ut_a(!lock_table_other_has_incompatible(
lock->trx, 0, table,
lock_get_mode(lock)));
} else {
ut_a(lock_table_has_to_wait_in_queue(lock));
}
lock = UT_LIST_GET_NEXT(un_member.tab_lock.locks, lock);
}
return(TRUE);
}
/*********************************************************************//**
Validates the lock queue on a single record.
@return TRUE if ok */
static
ibool
lock_rec_queue_validate(
/*====================*/
const buf_block_t* block, /*!< in: buffer block containing rec */
const rec_t* rec, /*!< in: record to look at */
dict_index_t* index, /*!< in: index, or NULL if not known */
const ulint* offsets)/*!< in: rec_get_offsets(rec, index) */
{
trx_t* impl_trx;
lock_t* lock;
ulint heap_no;
ut_a(rec);
ut_a(block->frame == page_align(rec));
ut_ad(rec_offs_validate(rec, index, offsets));
ut_ad(!page_rec_is_comp(rec) == !rec_offs_comp(offsets));
heap_no = page_rec_get_heap_no(rec);
lock_mutex_enter_kernel();
if (!page_rec_is_user_rec(rec)) {
lock = lock_rec_get_first(block, heap_no);
while (lock) {
switch(lock->trx->conc_state) {
case TRX_ACTIVE:
case TRX_PREPARED:
case TRX_COMMITTED_IN_MEMORY:
break;
default:
ut_error;
}
ut_a(trx_in_trx_list(lock->trx));
if (lock_get_wait(lock)) {
ut_a(lock_rec_has_to_wait_in_queue(lock));
}
if (index) {
ut_a(lock->index == index);
}
lock = lock_rec_get_next(heap_no, lock);
}
lock_mutex_exit_kernel();
return(TRUE);
}
if (!index);
else if (dict_index_is_clust(index)) {
impl_trx = lock_clust_rec_some_has_impl(rec, index, offsets);
if (impl_trx
&& lock_rec_other_has_expl_req(LOCK_S, 0, LOCK_WAIT,
block, heap_no, impl_trx)) {
ut_a(lock_rec_has_expl(LOCK_X | LOCK_REC_NOT_GAP,
block, heap_no, impl_trx));
}
#if 0
} else {
/* The kernel mutex may get released temporarily in the
next function call: we have to release lock table mutex
to obey the latching order */
/* If this thread is holding the file space latch
(fil_space_t::latch), the following check WILL break
latching order and may cause a deadlock of threads. */
/* NOTE: This is a bogus check that would fail in the
following case: Our transaction is updating a
row. After it has updated the clustered index record,
it goes to a secondary index record and finds someone
else holding an explicit S- or X-lock on that
secondary index record, presumably from a locking
read. Our transaction cannot update the secondary
index immediately, but places a waiting X-lock request
on the secondary index record. There is nothing
illegal in this. The assertion is simply too strong. */
/* From the locking point of view, each secondary
index is a separate table. A lock that is held on
secondary index rec does not give any rights to modify
or read the clustered index rec. Therefore, we can
think of the sec index as a separate 'table' from the
clust index 'table'. Conversely, a transaction that
has acquired a lock on and modified a clustered index
record may need to wait for a lock on the
corresponding record in a secondary index. */
impl_trx = lock_sec_rec_some_has_impl_off_kernel(
rec, index, offsets);
if (impl_trx
&& lock_rec_other_has_expl_req(LOCK_S, 0, LOCK_WAIT,
block, heap_no, impl_trx)) {
ut_a(lock_rec_has_expl(LOCK_X | LOCK_REC_NOT_GAP,
block, heap_no, impl_trx));
}
#endif
}
lock = lock_rec_get_first(block, heap_no);
while (lock) {
ut_a(lock->trx->conc_state == TRX_ACTIVE
|| lock->trx->conc_state == TRX_PREPARED
|| lock->trx->conc_state == TRX_COMMITTED_IN_MEMORY);
ut_a(trx_in_trx_list(lock->trx));
if (index) {
ut_a(lock->index == index);
}
if (!lock_rec_get_gap(lock) && !lock_get_wait(lock)) {
enum lock_mode mode;
if (lock_get_mode(lock) == LOCK_S) {
mode = LOCK_X;
} else {
mode = LOCK_S;
}
ut_a(!lock_rec_other_has_expl_req(
mode, 0, 0, block, heap_no, lock->trx));
} else if (lock_get_wait(lock) && !lock_rec_get_gap(lock)) {
ut_a(lock_rec_has_to_wait_in_queue(lock));
}
lock = lock_rec_get_next(heap_no, lock);
}
lock_mutex_exit_kernel();
return(TRUE);
}
/*********************************************************************//**
Validates the record lock queues on a page.
@return TRUE if ok */
static
ibool
lock_rec_validate_page(
/*===================*/
ulint space, /*!< in: space id */
ulint zip_size,/*!< in: compressed page size in bytes
or 0 for uncompressed pages */
ulint page_no)/*!< in: page number */
{
dict_index_t* index;
buf_block_t* block;
const page_t* page;
lock_t* lock;
const rec_t* rec;
ulint nth_lock = 0;
ulint nth_bit = 0;
ulint i;
mtr_t mtr;
mem_heap_t* heap = NULL;
ulint offsets_[REC_OFFS_NORMAL_SIZE];
ulint* offsets = offsets_;
rec_offs_init(offsets_);
ut_ad(!mutex_own(&kernel_mutex));
mtr_start(&mtr);
ut_ad(zip_size != ULINT_UNDEFINED);
block = buf_page_get(space, zip_size, page_no, RW_X_LATCH, &mtr);
buf_block_dbg_add_level(block, SYNC_NO_ORDER_CHECK);
page = block->frame;
lock_mutex_enter_kernel();
loop:
lock = lock_rec_get_first_on_page_addr(space, page_no);
if (!lock) {
goto function_exit;
}
for (i = 0; i < nth_lock; i++) {
lock = lock_rec_get_next_on_page(lock);
if (!lock) {
goto function_exit;
}
}
ut_a(trx_in_trx_list(lock->trx));
ut_a(lock->trx->conc_state == TRX_ACTIVE
|| lock->trx->conc_state == TRX_PREPARED
|| lock->trx->conc_state == TRX_COMMITTED_IN_MEMORY);
# ifdef UNIV_SYNC_DEBUG
/* Only validate the record queues when this thread is not
holding a space->latch. Deadlocks are possible due to
latching order violation when UNIV_DEBUG is defined while
UNIV_SYNC_DEBUG is not. */
if (!sync_thread_levels_contains(SYNC_FSP))
# endif /* UNIV_SYNC_DEBUG */
for (i = nth_bit; i < lock_rec_get_n_bits(lock); i++) {
if (i == 1 || lock_rec_get_nth_bit(lock, i)) {
index = lock->index;
rec = page_find_rec_with_heap_no(page, i);
ut_a(rec);
offsets = rec_get_offsets(rec, index, offsets,
ULINT_UNDEFINED, &heap);
fprintf(stderr,
"Validating %lu %lu\n",
(ulong) space, (ulong) page_no);
lock_mutex_exit_kernel();
/* If this thread is holding the file space
latch (fil_space_t::latch), the following
check WILL break the latching order and may
cause a deadlock of threads. */
lock_rec_queue_validate(block, rec, index, offsets);
lock_mutex_enter_kernel();
nth_bit = i + 1;
goto loop;
}
}
nth_bit = 0;
nth_lock++;
goto loop;
function_exit:
lock_mutex_exit_kernel();
mtr_commit(&mtr);
if (UNIV_LIKELY_NULL(heap)) {
mem_heap_free(heap);
}
return(TRUE);
}
/*********************************************************************//**
Validates the lock system.
@return TRUE if ok */
static
ibool
lock_validate(void)
/*===============*/
{
lock_t* lock;
trx_t* trx;
dulint limit;
ulint space;
ulint page_no;
ulint i;
lock_mutex_enter_kernel();
trx = UT_LIST_GET_FIRST(trx_sys->trx_list);
while (trx) {
lock = UT_LIST_GET_FIRST(trx->trx_locks);
while (lock) {
if (lock_get_type_low(lock) & LOCK_TABLE) {
lock_table_queue_validate(
lock->un_member.tab_lock.table);
}
lock = UT_LIST_GET_NEXT(trx_locks, lock);
}
trx = UT_LIST_GET_NEXT(trx_list, trx);
}
for (i = 0; i < hash_get_n_cells(lock_sys->rec_hash); i++) {
limit = ut_dulint_zero;
for (;;) {
lock = HASH_GET_FIRST(lock_sys->rec_hash, i);
while (lock) {
ut_a(trx_in_trx_list(lock->trx));
space = lock->un_member.rec_lock.space;
page_no = lock->un_member.rec_lock.page_no;
if (ut_dulint_cmp(
ut_dulint_create(space, page_no),
limit) >= 0) {
break;
}
lock = HASH_GET_NEXT(hash, lock);
}
if (!lock) {
break;
}
lock_mutex_exit_kernel();
lock_rec_validate_page(space,
fil_space_get_zip_size(space),
page_no);
lock_mutex_enter_kernel();
limit = ut_dulint_create(space, page_no + 1);
}
}
lock_mutex_exit_kernel();
return(TRUE);
}
#endif /* UNIV_DEBUG */
/*============ RECORD LOCK CHECKS FOR ROW OPERATIONS ====================*/
/*********************************************************************//**
Checks if locks of other transactions prevent an immediate insert of
a record. If they do, first tests if the query thread should anyway
be suspended for some reason; if not, then puts the transaction and
the query thread to the lock wait state and inserts a waiting request
for a gap x-lock to the lock queue.
@return DB_SUCCESS, DB_LOCK_WAIT, DB_DEADLOCK, or DB_QUE_THR_SUSPENDED */
UNIV_INTERN
ulint
lock_rec_insert_check_and_lock(
/*===========================*/
ulint flags, /*!< in: if BTR_NO_LOCKING_FLAG bit is
set, does nothing */
const rec_t* rec, /*!< in: record after which to insert */
buf_block_t* block, /*!< in/out: buffer block of rec */
dict_index_t* index, /*!< in: index */
que_thr_t* thr, /*!< in: query thread */
mtr_t* mtr, /*!< in/out: mini-transaction */
ibool* inherit)/*!< out: set to TRUE if the new
inserted record maybe should inherit
LOCK_GAP type locks from the successor
record */
{
const rec_t* next_rec;
trx_t* trx;
lock_t* lock;
ulint err;
ulint next_rec_heap_no;
ut_ad(block->frame == page_align(rec));
if (flags & BTR_NO_LOCKING_FLAG) {
return(DB_SUCCESS);
}
trx = thr_get_trx(thr);
next_rec = page_rec_get_next_const(rec);
next_rec_heap_no = page_rec_get_heap_no(next_rec);
lock_mutex_enter_kernel();
/* When inserting a record into an index, the table must be at
least IX-locked or we must be building an index, in which case
the table must be at least S-locked. */
ut_ad(lock_table_has(trx, index->table, LOCK_IX)
|| (*index->name == TEMP_INDEX_PREFIX
&& lock_table_has(trx, index->table, LOCK_S)));
lock = lock_rec_get_first(block, next_rec_heap_no);
if (UNIV_LIKELY(lock == NULL)) {
/* We optimize CPU time usage in the simplest case */
lock_mutex_exit_kernel();
if (!dict_index_is_clust(index)) {
/* Update the page max trx id field */
page_update_max_trx_id(block,
buf_block_get_page_zip(block),
trx->id, mtr);
}
*inherit = FALSE;
return(DB_SUCCESS);
}
*inherit = TRUE;
/* If another transaction has an explicit lock request which locks
the gap, waiting or granted, on the successor, the insert has to wait.
An exception is the case where the lock by the another transaction
is a gap type lock which it placed to wait for its turn to insert. We
do not consider that kind of a lock conflicting with our insert. This
eliminates an unnecessary deadlock which resulted when 2 transactions
had to wait for their insert. Both had waiting gap type lock requests
on the successor, which produced an unnecessary deadlock. */
if (lock_rec_other_has_conflicting(
LOCK_X | LOCK_GAP | LOCK_INSERT_INTENTION,
block, next_rec_heap_no, trx)) {
/* Note that we may get DB_SUCCESS also here! */
err = lock_rec_enqueue_waiting(LOCK_X | LOCK_GAP
| LOCK_INSERT_INTENTION,
block, next_rec_heap_no,
index, thr);
} else {
err = DB_SUCCESS;
}
lock_mutex_exit_kernel();
switch (err) {
case DB_SUCCESS_LOCKED_REC:
err = DB_SUCCESS;
/* fall through */
case DB_SUCCESS:
if (dict_index_is_clust(index)) {
break;
}
/* Update the page max trx id field */
page_update_max_trx_id(block,
buf_block_get_page_zip(block),
trx->id, mtr);
}
#ifdef UNIV_DEBUG
{
mem_heap_t* heap = NULL;
ulint offsets_[REC_OFFS_NORMAL_SIZE];
const ulint* offsets;
rec_offs_init(offsets_);
offsets = rec_get_offsets(next_rec, index, offsets_,
ULINT_UNDEFINED, &heap);
ut_ad(lock_rec_queue_validate(block,
next_rec, index, offsets));
if (UNIV_LIKELY_NULL(heap)) {
mem_heap_free(heap);
}
}
#endif /* UNIV_DEBUG */
return(err);
}
/*********************************************************************//**
If a transaction has an implicit x-lock on a record, but no explicit x-lock
set on the record, sets one for it. NOTE that in the case of a secondary
index, the kernel mutex may get temporarily released. */
static
void
lock_rec_convert_impl_to_expl(
/*==========================*/
const buf_block_t* block, /*!< in: buffer block of rec */
const rec_t* rec, /*!< in: user record on page */
dict_index_t* index, /*!< in: index of record */
const ulint* offsets)/*!< in: rec_get_offsets(rec, index) */
{
trx_t* impl_trx;
ut_ad(mutex_own(&kernel_mutex));
ut_ad(page_rec_is_user_rec(rec));
ut_ad(rec_offs_validate(rec, index, offsets));
ut_ad(!page_rec_is_comp(rec) == !rec_offs_comp(offsets));
if (dict_index_is_clust(index)) {
impl_trx = lock_clust_rec_some_has_impl(rec, index, offsets);
} else {
impl_trx = lock_sec_rec_some_has_impl_off_kernel(
rec, index, offsets);
}
if (impl_trx) {
ulint heap_no = page_rec_get_heap_no(rec);
/* If the transaction has no explicit x-lock set on the
record, set one for it */
if (!lock_rec_has_expl(LOCK_X | LOCK_REC_NOT_GAP, block,
heap_no, impl_trx)) {
lock_rec_add_to_queue(
LOCK_REC | LOCK_X | LOCK_REC_NOT_GAP,
block, heap_no, index, impl_trx);
}
}
}
/*********************************************************************//**
Checks if locks of other transactions prevent an immediate modify (update,
delete mark, or delete unmark) of a clustered index record. If they do,
first tests if the query thread should anyway be suspended for some
reason; if not, then puts the transaction and the query thread to the
lock wait state and inserts a waiting request for a record x-lock to the
lock queue.
@return DB_SUCCESS, DB_LOCK_WAIT, DB_DEADLOCK, or DB_QUE_THR_SUSPENDED */
UNIV_INTERN
ulint
lock_clust_rec_modify_check_and_lock(
/*=================================*/
ulint flags, /*!< in: if BTR_NO_LOCKING_FLAG
bit is set, does nothing */
const buf_block_t* block, /*!< in: buffer block of rec */
const rec_t* rec, /*!< in: record which should be
modified */
dict_index_t* index, /*!< in: clustered index */
const ulint* offsets,/*!< in: rec_get_offsets(rec, index) */
que_thr_t* thr) /*!< in: query thread */
{
ulint err;
ulint heap_no;
ut_ad(rec_offs_validate(rec, index, offsets));
ut_ad(dict_index_is_clust(index));
ut_ad(block->frame == page_align(rec));
if (flags & BTR_NO_LOCKING_FLAG) {
return(DB_SUCCESS);
}
heap_no = rec_offs_comp(offsets)
? rec_get_heap_no_new(rec)
: rec_get_heap_no_old(rec);
lock_mutex_enter_kernel();
ut_ad(lock_table_has(thr_get_trx(thr), index->table, LOCK_IX));
/* If a transaction has no explicit x-lock set on the record, set one
for it */
lock_rec_convert_impl_to_expl(block, rec, index, offsets);
err = lock_rec_lock(TRUE, LOCK_X | LOCK_REC_NOT_GAP,
block, heap_no, index, thr);
lock_mutex_exit_kernel();
ut_ad(lock_rec_queue_validate(block, rec, index, offsets));
if (UNIV_UNLIKELY(err == DB_SUCCESS_LOCKED_REC)) {
err = DB_SUCCESS;
}
return(err);
}
/*********************************************************************//**
Checks if locks of other transactions prevent an immediate modify (delete
mark or delete unmark) of a secondary index record.
@return DB_SUCCESS, DB_LOCK_WAIT, DB_DEADLOCK, or DB_QUE_THR_SUSPENDED */
UNIV_INTERN
ulint
lock_sec_rec_modify_check_and_lock(
/*===============================*/
ulint flags, /*!< in: if BTR_NO_LOCKING_FLAG
bit is set, does nothing */
buf_block_t* block, /*!< in/out: buffer block of rec */
const rec_t* rec, /*!< in: record which should be
modified; NOTE: as this is a secondary
index, we always have to modify the
clustered index record first: see the
comment below */
dict_index_t* index, /*!< in: secondary index */
que_thr_t* thr, /*!< in: query thread */
mtr_t* mtr) /*!< in/out: mini-transaction */
{
ulint err;
ulint heap_no;
ut_ad(!dict_index_is_clust(index));
ut_ad(block->frame == page_align(rec));
if (flags & BTR_NO_LOCKING_FLAG) {
return(DB_SUCCESS);
}
heap_no = page_rec_get_heap_no(rec);
/* Another transaction cannot have an implicit lock on the record,
because when we come here, we already have modified the clustered
index record, and this would not have been possible if another active
transaction had modified this secondary index record. */
lock_mutex_enter_kernel();
ut_ad(lock_table_has(thr_get_trx(thr), index->table, LOCK_IX));
err = lock_rec_lock(TRUE, LOCK_X | LOCK_REC_NOT_GAP,
block, heap_no, index, thr);
lock_mutex_exit_kernel();
#ifdef UNIV_DEBUG
{
mem_heap_t* heap = NULL;
ulint offsets_[REC_OFFS_NORMAL_SIZE];
const ulint* offsets;
rec_offs_init(offsets_);
offsets = rec_get_offsets(rec, index, offsets_,
ULINT_UNDEFINED, &heap);
ut_ad(lock_rec_queue_validate(block, rec, index, offsets));
if (UNIV_LIKELY_NULL(heap)) {
mem_heap_free(heap);
}
}
#endif /* UNIV_DEBUG */
if (err == DB_SUCCESS || err == DB_SUCCESS_LOCKED_REC) {
/* Update the page max trx id field */
/* It might not be necessary to do this if
err == DB_SUCCESS (no new lock created),
but it should not cost too much performance. */
page_update_max_trx_id(block,
buf_block_get_page_zip(block),
thr_get_trx(thr)->id, mtr);
err = DB_SUCCESS;
}
return(err);
}
/*********************************************************************//**
Like lock_clust_rec_read_check_and_lock(), but reads a
secondary index record.
@return DB_SUCCESS, DB_SUCCESS_LOCKED_REC, DB_LOCK_WAIT, DB_DEADLOCK,
or DB_QUE_THR_SUSPENDED */
UNIV_INTERN
enum db_err
lock_sec_rec_read_check_and_lock(
/*=============================*/
ulint flags, /*!< in: if BTR_NO_LOCKING_FLAG
bit is set, does nothing */
const buf_block_t* block, /*!< in: buffer block of rec */
const rec_t* rec, /*!< in: user record or page
supremum record which should
be read or passed over by a
read cursor */
dict_index_t* index, /*!< in: secondary index */
const ulint* offsets,/*!< in: rec_get_offsets(rec, index) */
enum lock_mode mode, /*!< in: mode of the lock which
the read cursor should set on
records: LOCK_S or LOCK_X; the
latter is possible in
SELECT FOR UPDATE */
ulint gap_mode,/*!< in: LOCK_ORDINARY, LOCK_GAP, or
LOCK_REC_NOT_GAP */
que_thr_t* thr) /*!< in: query thread */
{
enum db_err err;
ulint heap_no;
ut_ad(!dict_index_is_clust(index));
ut_ad(block->frame == page_align(rec));
ut_ad(page_rec_is_user_rec(rec) || page_rec_is_supremum(rec));
ut_ad(rec_offs_validate(rec, index, offsets));
ut_ad(mode == LOCK_X || mode == LOCK_S);
if (flags & BTR_NO_LOCKING_FLAG) {
return(DB_SUCCESS);
}
heap_no = page_rec_get_heap_no(rec);
lock_mutex_enter_kernel();
ut_ad(mode != LOCK_X
|| lock_table_has(thr_get_trx(thr), index->table, LOCK_IX));
ut_ad(mode != LOCK_S
|| lock_table_has(thr_get_trx(thr), index->table, LOCK_IS));
/* Some transaction may have an implicit x-lock on the record only
if the max trx id for the page >= min trx id for the trx list or a
database recovery is running. */
if (((ut_dulint_cmp(page_get_max_trx_id(block->frame),
trx_list_get_min_trx_id()) >= 0)
|| recv_recovery_is_on())
&& !page_rec_is_supremum(rec)) {
lock_rec_convert_impl_to_expl(block, rec, index, offsets);
}
err = lock_rec_lock(FALSE, mode | gap_mode,
block, heap_no, index, thr);
lock_mutex_exit_kernel();
ut_ad(lock_rec_queue_validate(block, rec, index, offsets));
return(err);
}
/*********************************************************************//**
Checks if locks of other transactions prevent an immediate read, or passing
over by a read cursor, of a clustered index record. If they do, first tests
if the query thread should anyway be suspended for some reason; if not, then
puts the transaction and the query thread to the lock wait state and inserts a
waiting request for a record lock to the lock queue. Sets the requested mode
lock on the record.
@return DB_SUCCESS, DB_SUCCESS_LOCKED_REC, DB_LOCK_WAIT, DB_DEADLOCK,
or DB_QUE_THR_SUSPENDED */
UNIV_INTERN
enum db_err
lock_clust_rec_read_check_and_lock(
/*===============================*/
ulint flags, /*!< in: if BTR_NO_LOCKING_FLAG
bit is set, does nothing */
const buf_block_t* block, /*!< in: buffer block of rec */
const rec_t* rec, /*!< in: user record or page
supremum record which should
be read or passed over by a
read cursor */
dict_index_t* index, /*!< in: clustered index */
const ulint* offsets,/*!< in: rec_get_offsets(rec, index) */
enum lock_mode mode, /*!< in: mode of the lock which
the read cursor should set on
records: LOCK_S or LOCK_X; the
latter is possible in
SELECT FOR UPDATE */
ulint gap_mode,/*!< in: LOCK_ORDINARY, LOCK_GAP, or
LOCK_REC_NOT_GAP */
que_thr_t* thr) /*!< in: query thread */
{
enum db_err err;
ulint heap_no;
ut_ad(dict_index_is_clust(index));
ut_ad(block->frame == page_align(rec));
ut_ad(page_rec_is_user_rec(rec) || page_rec_is_supremum(rec));
ut_ad(gap_mode == LOCK_ORDINARY || gap_mode == LOCK_GAP
|| gap_mode == LOCK_REC_NOT_GAP);
ut_ad(rec_offs_validate(rec, index, offsets));
if (flags & BTR_NO_LOCKING_FLAG) {
return(DB_SUCCESS);
}
heap_no = page_rec_get_heap_no(rec);
lock_mutex_enter_kernel();
ut_ad(mode != LOCK_X
|| lock_table_has(thr_get_trx(thr), index->table, LOCK_IX));
ut_ad(mode != LOCK_S
|| lock_table_has(thr_get_trx(thr), index->table, LOCK_IS));
if (UNIV_LIKELY(heap_no != PAGE_HEAP_NO_SUPREMUM)) {
lock_rec_convert_impl_to_expl(block, rec, index, offsets);
}
err = lock_rec_lock(FALSE, mode | gap_mode,
block, heap_no, index, thr);
lock_mutex_exit_kernel();
ut_ad(lock_rec_queue_validate(block, rec, index, offsets));
return(err);
}
/*********************************************************************//**
Checks if locks of other transactions prevent an immediate read, or passing
over by a read cursor, of a clustered index record. If they do, first tests
if the query thread should anyway be suspended for some reason; if not, then
puts the transaction and the query thread to the lock wait state and inserts a
waiting request for a record lock to the lock queue. Sets the requested mode
lock on the record. This is an alternative version of
lock_clust_rec_read_check_and_lock() that does not require the parameter
"offsets".
@return DB_SUCCESS, DB_LOCK_WAIT, DB_DEADLOCK, or DB_QUE_THR_SUSPENDED */
UNIV_INTERN
ulint
lock_clust_rec_read_check_and_lock_alt(
/*===================================*/
ulint flags, /*!< in: if BTR_NO_LOCKING_FLAG
bit is set, does nothing */
const buf_block_t* block, /*!< in: buffer block of rec */
const rec_t* rec, /*!< in: user record or page
supremum record which should
be read or passed over by a
read cursor */
dict_index_t* index, /*!< in: clustered index */
enum lock_mode mode, /*!< in: mode of the lock which
the read cursor should set on
records: LOCK_S or LOCK_X; the
latter is possible in
SELECT FOR UPDATE */
ulint gap_mode,/*!< in: LOCK_ORDINARY, LOCK_GAP, or
LOCK_REC_NOT_GAP */
que_thr_t* thr) /*!< in: query thread */
{
mem_heap_t* tmp_heap = NULL;
ulint offsets_[REC_OFFS_NORMAL_SIZE];
ulint* offsets = offsets_;
ulint err;
rec_offs_init(offsets_);
offsets = rec_get_offsets(rec, index, offsets,
ULINT_UNDEFINED, &tmp_heap);
err = lock_clust_rec_read_check_and_lock(flags, block, rec, index,
offsets, mode, gap_mode, thr);
if (tmp_heap) {
mem_heap_free(tmp_heap);
}
if (UNIV_UNLIKELY(err == DB_SUCCESS_LOCKED_REC)) {
err = DB_SUCCESS;
}
return(err);
}
/*******************************************************************//**
Release the last lock from the transaction's autoinc locks. */
UNIV_INLINE
void
lock_release_autoinc_last_lock(
/*===========================*/
ib_vector_t* autoinc_locks) /*!< in/out: vector of AUTOINC locks */
{
ulint last;
lock_t* lock;
ut_ad(mutex_own(&kernel_mutex));
ut_a(!ib_vector_is_empty(autoinc_locks));
/* The lock to be release must be the last lock acquired. */
last = ib_vector_size(autoinc_locks) - 1;
lock = ib_vector_get(autoinc_locks, last);
/* Should have only AUTOINC locks in the vector. */
ut_a(lock_get_mode(lock) == LOCK_AUTO_INC);
ut_a(lock_get_type(lock) == LOCK_TABLE);
ut_a(lock->un_member.tab_lock.table != NULL);
/* This will remove the lock from the trx autoinc_locks too. */
lock_table_dequeue(lock);
}
/*******************************************************************//**
Check if a transaction holds any autoinc locks.
@return TRUE if the transaction holds any AUTOINC locks. */
UNIV_INTERN
ibool
lock_trx_holds_autoinc_locks(
/*=========================*/
const trx_t* trx) /*!< in: transaction */
{
ut_a(trx->autoinc_locks != NULL);
return(!ib_vector_is_empty(trx->autoinc_locks));
}
/*******************************************************************//**
Release all the transaction's autoinc locks. */
UNIV_INTERN
void
lock_release_autoinc_locks(
/*=======================*/
trx_t* trx) /*!< in/out: transaction */
{
ut_ad(mutex_own(&kernel_mutex));
ut_a(trx->autoinc_locks != NULL);
/* We release the locks in the reverse order. This is to
avoid searching the vector for the element to delete at
the lower level. See (lock_table_remove_low()) for details. */
while (!ib_vector_is_empty(trx->autoinc_locks)) {
/* lock_table_remove_low() will also remove the lock from
the transaction's autoinc_locks vector. */
lock_release_autoinc_last_lock(trx->autoinc_locks);
}
/* Should release all locks. */
ut_a(ib_vector_is_empty(trx->autoinc_locks));
}
/*******************************************************************//**
Gets the type of a lock. Non-inline version for using outside of the
lock module.
@return LOCK_TABLE or LOCK_REC */
UNIV_INTERN
ulint
lock_get_type(
/*==========*/
const lock_t* lock) /*!< in: lock */
{
return(lock_get_type_low(lock));
}
/*******************************************************************//**
Gets the id of the transaction owning a lock.
@return transaction id */
UNIV_INTERN
ullint
lock_get_trx_id(
/*============*/
const lock_t* lock) /*!< in: lock */
{
return(trx_get_id(lock->trx));
}
/*******************************************************************//**
Gets the mode of a lock in a human readable string.
The string should not be free()'d or modified.
@return lock mode */
UNIV_INTERN
const char*
lock_get_mode_str(
/*==============*/
const lock_t* lock) /*!< in: lock */
{
ibool is_gap_lock;
is_gap_lock = lock_get_type_low(lock) == LOCK_REC
&& lock_rec_get_gap(lock);
switch (lock_get_mode(lock)) {
case LOCK_S:
if (is_gap_lock) {
return("S,GAP");
} else {
return("S");
}
case LOCK_X:
if (is_gap_lock) {
return("X,GAP");
} else {
return("X");
}
case LOCK_IS:
if (is_gap_lock) {
return("IS,GAP");
} else {
return("IS");
}
case LOCK_IX:
if (is_gap_lock) {
return("IX,GAP");
} else {
return("IX");
}
case LOCK_AUTO_INC:
return("AUTO_INC");
default:
return("UNKNOWN");
}
}
/*******************************************************************//**
Gets the type of a lock in a human readable string.
The string should not be free()'d or modified.
@return lock type */
UNIV_INTERN
const char*
lock_get_type_str(
/*==============*/
const lock_t* lock) /*!< in: lock */
{
switch (lock_get_type_low(lock)) {
case LOCK_REC:
return("RECORD");
case LOCK_TABLE:
return("TABLE");
default:
return("UNKNOWN");
}
}
/*******************************************************************//**
Gets the table on which the lock is.
@return table */
UNIV_INLINE
dict_table_t*
lock_get_table(
/*===========*/
const lock_t* lock) /*!< in: lock */
{
switch (lock_get_type_low(lock)) {
case LOCK_REC:
return(lock->index->table);
case LOCK_TABLE:
return(lock->un_member.tab_lock.table);
default:
ut_error;
return(NULL);
}
}
/*******************************************************************//**
Gets the id of the table on which the lock is.
@return id of the table */
UNIV_INTERN
ullint
lock_get_table_id(
/*==============*/
const lock_t* lock) /*!< in: lock */
{
dict_table_t* table;
table = lock_get_table(lock);
return((ullint)ut_conv_dulint_to_longlong(table->id));
}
/*******************************************************************//**
Gets the name of the table on which the lock is.
The string should not be free()'d or modified.
@return name of the table */
UNIV_INTERN
const char*
lock_get_table_name(
/*================*/
const lock_t* lock) /*!< in: lock */
{
dict_table_t* table;
table = lock_get_table(lock);
return(table->name);
}
/*******************************************************************//**
For a record lock, gets the index on which the lock is.
@return index */
UNIV_INTERN
const dict_index_t*
lock_rec_get_index(
/*===============*/
const lock_t* lock) /*!< in: lock */
{
ut_a(lock_get_type_low(lock) == LOCK_REC);
return(lock->index);
}
/*******************************************************************//**
For a record lock, gets the name of the index on which the lock is.
The string should not be free()'d or modified.
@return name of the index */
UNIV_INTERN
const char*
lock_rec_get_index_name(
/*====================*/
const lock_t* lock) /*!< in: lock */
{
ut_a(lock_get_type_low(lock) == LOCK_REC);
return(lock->index->name);
}
/*******************************************************************//**
For a record lock, gets the tablespace number on which the lock is.
@return tablespace number */
UNIV_INTERN
ulint
lock_rec_get_space_id(
/*==================*/
const lock_t* lock) /*!< in: lock */
{
ut_a(lock_get_type_low(lock) == LOCK_REC);
return(lock->un_member.rec_lock.space);
}
/*******************************************************************//**
For a record lock, gets the page number on which the lock is.
@return page number */
UNIV_INTERN
ulint
lock_rec_get_page_no(
/*=================*/
const lock_t* lock) /*!< in: lock */
{
ut_a(lock_get_type_low(lock) == LOCK_REC);
return(lock->un_member.rec_lock.page_no);
}
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