mirror/mariadb
1
0
Fork 0
mirror of https://github.com/MariaDB/server.git synced 2025-01-16 20:12:31 +01:00
Code Issues Projects Releases Packages Wiki Activity Actions
mariadb/mysql-test/r/commit_1innodb.result
Davi Arnaut b0035c76d4 Bug#54453: Failing assertion: trx->active_trans when renaming a 
table with active trx

Essentially, the problem is that InnoDB does a implicit commit
when a cursor (table handler) is unlocked/closed, creating
a dissonance between the transaction state within the server
layer and the storage engine layer. Theoretically, a statement
transaction can encompass several table instances in a similar
manner to a multiple statement transaction, hence it does not
make sense to limit a statement transaction to the lifetime of
the table instances (cursors) used within it.

Since this particular instance of the problem is only triggerable
on 5.1 and is masked on 5.5 due 2PC being skipped (assertion is in
the prepare phase of a 2PC), the solution (which is less risky) is
to explicitly end the transaction before the cached table is unlock
on rename table.

The patch is to be null merged into trunk.

mysql-test/include/commit.inc:
  Fix counters, the binlog engine does not get involved anymore.
mysql-test/suite/innodb_plugin/r/innodb_bug54453.result:
  Add test case result for Bug#54453
mysql-test/suite/innodb_plugin/t/innodb_bug54453.test:
  Add test case for Bug#54453
sql/sql_table.cc:
  End transaction as otherwise InnoDB will end it behind our backs.
2010-07-20 14:36:15 -03:00

891 lines
19 KiB
Text
Raw Blame History

set sql_mode=no_engine_substitution;
set storage_engine = InnoDB;
set autocommit=1;
drop table if exists t1;
drop table if exists t2;
drop table if exists t3;
drop function if exists f2;
drop procedure if exists bug12713_call;
drop procedure if exists bug12713_dump_spvars;
drop procedure if exists dummy;
create table t1 (a int);
create table t2 (a int unique);
create table t3 (a int);
set sql_mode=default;
insert into t1 (a) values (1), (2);
insert into t3 (a) values (1), (2);
create function f2(x int) returns int
begin
insert into t2 (a) values (x);
insert into t2 (a) values (x);
return x;
end|
set autocommit=0;
flush status;
insert into t2 (a) values (1001);
insert into t1 (a) values (f2(1));
ERROR 23000: Duplicate entry '1' for key 'a'
select * from t2;
a
1001
rollback;
select * from t2;
a
insert into t2 (a) values (1002);
insert into t3 (a) select f2(2) from t1;
ERROR 23000: Duplicate entry '2' for key 'a'
select * from t2;
a
1002
rollback;
select * from t2;
a
insert into t2 (a) values (1003);
update t1 set a= a + f2(3);
ERROR 23000: Duplicate entry '3' for key 'a'
select * from t2;
a
1003
rollback;
select * from t2;
a
insert into t2 (a) values (1004);
update t1, t3 set t1.a = 0, t3.a = 0 where (f2(4) = 4) and (t1.a = t3.a);
ERROR 23000: Duplicate entry '4' for key 'a'
select * from t2;
a
1004
rollback;
select * from t2;
a
insert into t2 (a) values (1005);
delete from t1 where (a = f2(5));
ERROR 23000: Duplicate entry '5' for key 'a'
select * from t2;
a
1005
rollback;
select * from t2;
a
insert into t2 (a) values (1006);
delete from t1, t3 using t1, t3 where (f2(6) = 6) ;
ERROR 23000: Duplicate entry '6' for key 'a'
select * from t2;
a
1006
rollback;
select * from t2;
a
insert into t2 (a) values (1007);
replace t1 values (f2(7));
ERROR 23000: Duplicate entry '7' for key 'a'
select * from t2;
a
1007
rollback;
select * from t2;
a
insert into t2 (a) values (1008);
replace into t3 (a) select f2(8) from t1;
ERROR 23000: Duplicate entry '8' for key 'a'
select * from t2;
a
1008
rollback;
select * from t2;
a
insert into t2 (a) values (1009);
select f2(9) from t1 ;
ERROR 23000: Duplicate entry '9' for key 'a'
select * from t2;
a
1009
rollback;
select * from t2;
a
insert into t2 (a) values (1010);
show databases where (f2(10) = 10);
ERROR 23000: Duplicate entry '10' for key 'a'
select * from t2;
a
1010
rollback;
select * from t2;
a
insert into t2 (a) values (1011);
show tables where (f2(11) = 11);
ERROR 23000: Duplicate entry '11' for key 'a'
select * from t2;
a
1011
rollback;
select * from t2;
a
insert into t2 (a) values (1012);
show triggers where (f2(12) = 12);
ERROR 23000: Duplicate entry '12' for key 'a'
select * from t2;
a
1012
rollback;
select * from t2;
a
insert into t2 (a) values (1013);
show table status where (f2(13) = 13);
ERROR 23000: Duplicate entry '13' for key 'a'
select * from t2;
a
1013
rollback;
select * from t2;
a
insert into t2 (a) values (1014);
show open tables where (f2(14) = 14);
ERROR 23000: Duplicate entry '14' for key 'a'
select * from t2;
a
1014
rollback;
select * from t2;
a
insert into t2 (a) values (1015);
show columns in mysql.proc where (f2(15) = 15);
ERROR 23000: Duplicate entry '15' for key 'a'
select * from t2;
a
1015
rollback;
select * from t2;
a
insert into t2 (a) values (1016);
show status where (f2(16) = 16);
ERROR 23000: Duplicate entry '16' for key 'a'
select * from t2;
a
1016
rollback;
select * from t2;
a
insert into t2 (a) values (1017);
show variables where (f2(17) = 17);
ERROR 23000: Duplicate entry '17' for key 'a'
select * from t2;
a
1017
rollback;
select * from t2;
a
insert into t2 (a) values (1018);
show charset where (f2(18) = 18);
ERROR 23000: Duplicate entry '18' for key 'a'
select * from t2;
a
1018
rollback;
select * from t2;
a
insert into t2 (a) values (1019);
show collation where (f2(19) = 19);
ERROR 23000: Duplicate entry '19' for key 'a'
select * from t2;
a
1019
rollback;
select * from t2;
a
# We need at least one procedure to make sure the WHERE clause is
# evaluated
create procedure dummy() begin end;
insert into t2 (a) values (1020);
show procedure status where (f2(20) = 20);
ERROR 23000: Duplicate entry '20' for key 'a'
select * from t2;
a
1020
rollback;
select * from t2;
a
drop procedure dummy;
insert into t2 (a) values (1021);
show function status where (f2(21) = 21);
ERROR 23000: Duplicate entry '21' for key 'a'
select * from t2;
a
1021
rollback;
select * from t2;
a
insert into t2 (a) values (1022);
prepare stmt from "insert into t1 (a) values (f2(22))";
execute stmt;
ERROR 23000: Duplicate entry '22' for key 'a'
select * from t2;
a
1022
rollback;
select * from t2;
a
insert into t2 (a) values (1023);
do (f2(23));
Warnings:
Error 1062 Duplicate entry '23' for key 'a'
select * from t2;
a
1023
rollback;
select * from t2;
a
create procedure bug12713_call ()
begin
insert into t2 (a) values (24);
insert into t2 (a) values (24);
end|
insert into t2 (a) values (1024);
call bug12713_call();
ERROR 23000: Duplicate entry '24' for key 'a'
select * from t2;
a
24
1024
rollback;
select * from t2;
a
=======================================================================
Testing select_to_file
=======================================================================
insert into t2 (a) values (1025);
select f2(25) into outfile "../tmp/dml.out" from t1;
ERROR 23000: Duplicate entry '25' for key 'a'
select * from t2;
a
1025
rollback;
select * from t2;
a
insert into t2 (a) values (1026);
load data infile "../../std_data/words.dat" into table t1 (a) set a:=f2(26);
ERROR 23000: Duplicate entry '26' for key 'a'
select * from t2;
a
1026
rollback;
select * from t2;
a
=======================================================================
Testing select_dumpvar
=======================================================================
insert into t2 (a) values (1027);
select f2(27) into @foo;
ERROR 23000: Duplicate entry '27' for key 'a'
select * from t2;
a
1027
rollback;
select * from t2;
a
=======================================================================
Testing Select_fetch_into_spvars
=======================================================================
create procedure bug12713_dump_spvars ()
begin
declare foo int;
declare continue handler for sqlexception
begin
select "Exception trapped";
end;
select f2(28) into foo;
select * from t2;
end|
insert into t2 (a) values (1028);
call bug12713_dump_spvars ();
Exception trapped
Exception trapped
a
1028
rollback;
select * from t2;
a
=======================================================================
Cleanup
=======================================================================
set autocommit=default;
drop table t1;
drop table t2;
drop table t3;
drop function f2;
drop procedure bug12713_call;
drop procedure bug12713_dump_spvars;
#
# Bug#12713 Error in a stored function called from a SELECT doesn't
# cause ROLLBACK of statem
#
# Verify that two-phase commit is not issued for read-only
# transactions.
#
# Verify that two-phase commit is issued for read-write transactions,
# even if the change is done inside a stored function called from
# SELECT or SHOW statement.
#
set autocommit=0;
drop table if exists t1;
drop table if exists t2;
drop function if exists f1;
drop procedure if exists p_verify_status_increment;
set @binlog_format=@@global.binlog_format;
set sql_mode=no_engine_substitution;
create table t1 (a int unique);
create table t2 (a int) engine=myisam;
set sql_mode=default;
#
# An auxiliary procedure to track Handler_prepare and Handler_commit
# statistics.
#
create procedure
p_verify_status_increment(commit_inc_mixed int, prepare_inc_mixed int,
commit_inc_row int, prepare_inc_row int)
begin
declare commit_inc int;
declare prepare_inc int;
declare old_commit_count int default ifnull(@commit_count, 0);
declare old_prepare_count int default ifnull(@prepare_count, 0);
declare c_res int;
# Use a cursor to have just one access to I_S instead of 2, it is very slow
# and amounts for over 90% of test CPU time
declare c cursor for
select variable_value
from information_schema.session_status
where variable_name='Handler_commit' or variable_name='Handler_prepare'
order by variable_name;
if @binlog_format = 'ROW' then
set commit_inc= commit_inc_row;
set prepare_inc= prepare_inc_row;
else
set commit_inc= commit_inc_mixed;
set prepare_inc= prepare_inc_mixed;
end if;
open c;
fetch c into c_res;
set @commit_count=c_res;
fetch c into c_res;
set @prepare_count=c_res;
close c;
if old_commit_count + commit_inc <> @commit_count then
select concat("Expected commit increment: ", commit_inc,
" actual: ", @commit_count - old_commit_count)
as 'ERROR';
elseif old_prepare_count + prepare_inc <> @prepare_count then
select concat("Expected prepare increment: ", prepare_inc,
" actual: ", @prepare_count - old_prepare_count)
as 'ERROR';
else
select '' as 'SUCCESS';
end if;
end|
# Reset Handler_commit and Handler_prepare counters
flush status;
#
# 1. Read-only statement: SELECT
#
select * from t1;
a
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
# 2. Read-write statement: INSERT, insert 1 row.
#
insert into t1 (a) values (1);
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
commit;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
# 3. Read-write statement: UPDATE, update 1 row.
#
update t1 set a=2;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
commit;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
# 4. Read-write statement: UPDATE, update 0 rows, 1 row matches WHERE
#
update t1 set a=2;
call p_verify_status_increment(2, 2, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(2, 2, 1, 0);
SUCCESS
# 5. Read-write statement: UPDATE, update 0 rows, 0 rows match WHERE
#
# In mixed replication mode, there is a read-only transaction
# in InnoDB and also the statement is written to the binary log.
# So we have two commits but no 2pc, since the first engine's
# transaction is read-only.
# In the row level replication mode, we only have the read-only
# transaction in InnoDB and nothing is written to the binary log.
#
update t1 set a=3 where a=1;
call p_verify_status_increment(2, 0, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(2, 0, 1, 0);
SUCCESS
# 6. Read-write statement: DELETE, delete 0 rows.
#
delete from t1 where a=1;
call p_verify_status_increment(2, 0, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(2, 0, 1, 0);
SUCCESS
# 7. Read-write statement: DELETE, delete 1 row.
#
delete from t1 where a=2;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
commit;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
# 8. Read-write statement: unqualified DELETE
#
# In statement or mixed replication mode, we call
# handler::ha_delete_all_rows() and write statement text
# to the binary log. This results in two read-write transactions.
# In row level replication mode, we do not call
# handler::ha_delete_all_rows(), but delete rows one by one.
# Since there are no rows, nothing is written to the binary log.
# Thus we have just one read-only transaction in InnoDB.
delete from t1;
call p_verify_status_increment(2, 2, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(2, 2, 1, 0);
SUCCESS
# 9. Read-write statement: REPLACE, change 1 row.
#
replace t1 set a=1;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
commit;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
# 10. Read-write statement: REPLACE, change 0 rows.
#
replace t1 set a=1;
call p_verify_status_increment(2, 2, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(2, 2, 1, 0);
SUCCESS
# 11. Read-write statement: IODKU, change 1 row.
#
insert t1 set a=1 on duplicate key update a=a+1;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
select * from t1;
a
2
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
# 12. Read-write statement: IODKU, change 0 rows.
#
insert t1 set a=2 on duplicate key update a=2;
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
# 13. Read-write statement: INSERT IGNORE, change 0 rows.
#
insert ignore t1 set a=2;
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
# 14. Read-write statement: INSERT IGNORE, change 1 row.
#
insert ignore t1 set a=1;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
commit;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
# 15. Read-write statement: UPDATE IGNORE, change 0 rows.
#
update ignore t1 set a=2 where a=1;
call p_verify_status_increment(2, 2, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(2, 2, 1, 0);
SUCCESS
#
# Create a stored function that modifies a
# non-transactional table. Demonstrate that changes in
# non-transactional tables do not affect the two phase commit
# algorithm.
#
create function f1() returns int
begin
insert t2 set a=2;
return 2;
end|
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
# 16. A function changes non-trans-table.
#
# For row-based logging, there is an extra commit for the
# non-transactional changes saved in the transaction cache to
# the binary log.
#
select f1();
f1()
2
call p_verify_status_increment(0, 0, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(0, 0, 1, 0);
SUCCESS
# 17. Read-only statement, a function changes non-trans-table.
#
# For row-based logging, there is an extra commit for the
# non-transactional changes saved in the transaction cache to
# the binary log.
#
select f1() from t1;
f1()
2
2
call p_verify_status_increment(1, 0, 2, 0);
SUCCESS
commit;
call p_verify_status_increment(1, 0, 2, 0);
SUCCESS
# 18. Read-write statement: UPDATE, change 0 (transactional) rows.
#
select count(*) from t2;
count(*)
3
update t1 set a=2 where a=f1()+10;
select count(*) from t2;
count(*)
5
call p_verify_status_increment(2, 0, 2, 0);
SUCCESS
commit;
call p_verify_status_increment(2, 0, 2, 0);
SUCCESS
#
# Replace the non-transactional table with a temporary
# transactional table. Demonstrate that a change to a temporary
# transactional table does not provoke 2-phase commit, although
# does trigger a commit and a binlog write (in statement mode).
#
drop table t2;
set sql_mode=no_engine_substitution;
create temporary table t2 (a int);
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
set sql_mode=default;
# 19. A function changes temp-trans-table.
#
select f1();
f1()
2
# Two commits because a binary log record is written
call p_verify_status_increment(2, 0, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(2, 0, 1, 0);
SUCCESS
# 20. Read-only statement, a function changes non-trans-table.
#
select f1() from t1;
f1()
2
2
# Two commits because a binary log record is written
call p_verify_status_increment(2, 0, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(2, 0, 1, 0);
SUCCESS
# 21. Read-write statement: UPDATE, change 0 (transactional) rows.
#
update t1 set a=2 where a=f1()+10;
call p_verify_status_increment(2, 0, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(2, 0, 1, 0);
SUCCESS
# 22. DDL: ALTER TEMPORARY TABLE, should not cause a 2pc
#
alter table t2 add column b int default 5;
# A commit is done internally by ALTER.
call p_verify_status_increment(2, 0, 2, 0);
SUCCESS
commit;
# There is nothing left to commit
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
# 23. DDL: RENAME TEMPORARY TABLE, does not start a transaction
# No test because of Bug#8729 "rename table fails on temporary table"
# 24. DDL: TRUNCATE TEMPORARY TABLE
truncate table t2;
call p_verify_status_increment(4, 0, 4, 0);
ERROR
Expected commit increment: 4 actual: 2
commit;
# There is nothing left to commit
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
# 25. Read-write statement: unqualified DELETE
delete from t2;
call p_verify_status_increment(2, 0, 1, 0);
SUCCESS
commit;
# There is nothing left to commit
call p_verify_status_increment(2, 0, 1, 0);
SUCCESS
# 25. DDL: DROP TEMPORARY TABLE, does not start a transaction
#
drop temporary table t2;
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
commit;
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
# 26. Verify that SET AUTOCOMMIT issues an implicit commit
#
insert t1 set a=3;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
set autocommit=1;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
rollback;
select a from t1 where a=3;
a
3
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
delete from t1 where a=3;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
commit;
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
set autocommit=0;
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
insert t1 set a=3;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
# Sic: not actually changing the value of autocommit
set autocommit=0;
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
rollback;
select a from t1 where a=3;
a
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
# 27. Savepoint management
#
insert t1 set a=3;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
savepoint a;
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
insert t1 set a=4;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
release savepoint a;
rollback;
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
select a from t1 where a=3;
a
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
commit;
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
# 28. Read-write statement: DO
#
create table t2 (a int);
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
do (select f1() from t1 where a=2);
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
commit;
call p_verify_status_increment(2, 2, 2, 2);
SUCCESS
# 29. Read-write statement: MULTI-DELETE
#
delete t1, t2 from t1 join t2 on (t1.a=t2.a) where t1.a=2;
commit;
call p_verify_status_increment(4, 4, 4, 4);
SUCCESS
# 30. Read-write statement: INSERT-SELECT, MULTI-UPDATE, REPLACE-SELECT
#
insert into t2 select a from t1;
commit;
replace into t2 select a from t1;
commit;
call p_verify_status_increment(8, 8, 8, 8);
SUCCESS
update t1, t2 set t1.a=4, t2.a=8 where t1.a=t2.a and t1.a=1;
commit;
call p_verify_status_increment(4, 4, 4, 4);
SUCCESS
# 31. DDL: various DDL with transactional tables
#
# Sic: no table is created.
create table if not exists t2 (a int) select 6 union select 7;
Warnings:
Note 1050 Table 't2' already exists
# Sic: first commits the statement, and then the transaction.
call p_verify_status_increment(4, 4, 4, 4);
SUCCESS
create table t3 select a from t2;
call p_verify_status_increment(4, 4, 4, 4);
SUCCESS
alter table t3 add column (b int);
call p_verify_status_increment(2, 0, 2, 0);
SUCCESS
alter table t3 rename t4;
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
rename table t4 to t3;
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
truncate table t3;
call p_verify_status_increment(4, 4, 4, 4);
SUCCESS
create view v1 as select * from t2;
call p_verify_status_increment(1, 0, 1, 0);
SUCCESS
check table t1;
Table Op Msg_type Msg_text
test.t1 check status OK
call p_verify_status_increment(3, 0, 3, 0);
SUCCESS
# Sic: after this bug is fixed, CHECK leaves no pending transaction
commit;
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
check table t1, t2, t3;
Table Op Msg_type Msg_text
test.t1 check status OK
test.t2 check status OK
test.t3 check status OK
call p_verify_status_increment(6, 0, 6, 0);
SUCCESS
commit;
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
drop view v1;
call p_verify_status_increment(0, 0, 0, 0);
SUCCESS
#
# Cleanup
#
drop table t1, t2, t3;
drop procedure p_verify_status_increment;
drop function f1;
Reference in a new issue View git blame Copy permalink