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Concurrency … the path to success and the path the failure
Let’s face it. Concurrency is a good thing when it comes to database applications. After all, if there is only a single user of your application, then chances are, it is not a successful application 
. Of course there are exceptions to this rule, but by and large, most of the applications we build are going to be used by large populations of users. And given the recent publicity of users data and privacy, we can also be pretty confident that we want the data in our applications to be correct at all times.
As a developer, it is absolutely critical to keep concurrency in mind when building applications. Here is a simple demonstration to thrust home the point.
The task assigned to the developer here is simple – transfer move all of the rows satisfying a particular condition from table T1 to table T2. Let’s create our database objects first:
SQL> create table t1 ( x int, y int, z int );
Table created.
SQL> create table t2 as select * from t1 where 1=0;
Table created.
SQL>
SQL> insert into t1
2 select rownum, rownum, rownum
3 from dual connect by level <= 10000;
10000 rows created.
SQL> commit;
Commit complete.
So table T1 has 10,000 rows and T2 is empty, and our condition to determine which rows to transfer will be X being non-zero. That happens to be all of the rows, but of course, it could be any filtering rule on the existing data. I’ve chosen all of the rows so I can keep the numbers easy to digest in the upcoming examples.
There is no such thing as a MOVE command in SQL, so we can implement this with two statements:
- INSERT-SELECT to copy the rows from T1 to T2
- DELETE to remove the rows we just copied.
Here is the simple PLSQL routine to do that, and a first test run of the code.
SQL>
SQL> set serverout on
SQL> begin
2 insert into t2 select * from t1 where x != 0;
3 delete from t1 where x != 0;
4 commit;
5 end;
6 /
PL/SQL procedure successfully completed.
SQL>
SQL> select count(*) from t1;
COUNT(*)
----------
0
1 row selected.
SQL> select count(*) from t2;
COUNT(*)
----------
10000
1 row selected.
SQL>
Everything looks fine doesn’t it? But it’s not. In fact, I’ll do what any good developer should be doing, and add some instrumentation to the code to get more information about its operations.
SQL> create table t1 ( x int, y int, z int );
Table created.
SQL> create table t2 as select * from t1 where 1=0;
Table created.
SQL>
SQL> insert into t1
2 select rownum, rownum, rownum
3 from dual connect by level <= 10000;
10000 rows created.
SQL> commit;
Commit complete.
SQL>
SQL> set serverout on
SQL> begin
2 insert into t2 select * from t1 where x != 0;
3 dbms_output.put_line(sql%rowcount);
4 delete from t1 where x != 0;
5 dbms_output.put_line(sql%rowcount);
6 commit;
7 end;
8 /
10000
10100 <=========== !!!!!
PL/SQL procedure successfully completed.
SQL>
SQL> select count(*) from t1;
COUNT(*)
----------
0
1 row selected.
SQL> select count(*) from t2;
COUNT(*)
----------
10000
1 row selected.
SQL>
SQL>
Look at the output from the PL/SQL block. I copied(inserted ) 10,000 rows from T1 to T2, but the deletion phase removed more than 10,000 rows. How was that possible? It is because databases are about concurrency. In another session, I had a simple script running that just adds new rows to the table continuously. As a developer, it is vital that you do not assume that you are the only person accessing or manipulating a table. My code in its existing form has corrupted the database, because 100 rows have been deleted that were never copied to T2. They’re gone forever!
So….onto some potential solutions. Lets try locking the rows first
SQL> create table t1 ( x int, y int, z int );
Table created.
SQL> create table t2 as select * from t1 where 1=0;
Table created.
SQL>
SQL> insert into t1
2 select rownum, rownum, rownum
3 from dual connect by level <= 10000;
10000 rows created.
SQL> commit;
Commit complete.
SQL> set serverout on
SQL> declare
2 cursor c is select * from t1 where x != 0 FOR UPDATE;
3 begin
4 open c;
5 insert into t2 select * from t1 where x != 0;
6 dbms_output.put_line(sql%rowcount);
7 delete from t1 where x != 0;
8 dbms_output.put_line(sql%rowcount);
9 commit;
10 close c;
11 end;
12 /
10000
10100
PL/SQL procedure successfully completed.
SQL>
SQL> select count(*) from t1;
COUNT(*)
----------
0
1 row selected.
SQL> select count(*) from t2;
COUNT(*)
----------
10000
1 row selected.
As you can see, that has not yielded any benefit because locking is only of benefit for locking existing rows. The new rows arriving from a separate session are unhindered, and hence my DELETE statement still picks up the new rows when it should not. I could workaround this by locking the entire table, but what if my filtering condition was only a small percentage of the rows? It seems overly aggressive to lock everyone out of the table just to copy a small subset of rows. In this case, I can use PL/SQL to help me out. Using the BULK COLLECT / BULK BIND facilities, I can restrict my DML operations to just the ROWIDs of the rows I am copying.
SQL> create table t1 ( x int, y int, z int );
Table created.
SQL> create table t2 as select * from t1 where 1=0;
Table created.
SQL>
SQL> insert into t1
2 select rownum, rownum, rownum
3 from dual connect by level <= 10000;
10000 rows created.
SQL> commit;
Commit complete.
SQL> set serverout on
SQL> declare
2 cursor c is select rowid rid, t1.* from t1 where x != 0 for update;
3 type array is table of c%rowtype index by pls_integer;
4 l_rows array;
5 l_idx int;
6 begin
7 open c;
8 loop
9 fetch c bulk collect into l_rows limit 20000;
10 exit when l_rows.count = 0;
11
12 forall i in 1 .. l_rows.count
13 insert into t2 values (
14 l_rows(i).x,
15 l_rows(i).y,
16 l_rows(i).z );
17 dbms_output.put_line(sql%rowcount);
18 forall i in 1 .. l_rows.count
19 delete from t1
20 where rowid = l_rows(i).rid;
21 dbms_output.put_line(sql%rowcount);
22 end loop;
23 end;
24 /
10000
10000
PL/SQL procedure successfully completed.
SQL>
SQL>
SQL> select count(*) from t1;
COUNT(*)
----------
147
1 row selected.
SQL> select count(*) from t2;
COUNT(*)
----------
10000
1 row selected.
I am collecting the 10000 ROWID’s of interest into an array, and then deleting only those rows. So even though new rows are arriving, I will never see them because they will not be in the set of ROWIDs that I am moving to table T2. We can see that during the operation, 147 new rows arrived in T1 from other sessions.
(Note: Normally you would choose a bulk collect size of perhaps 1000 or similar, and loop around repeated to avoid excessive PGA use. I bulk collected the entire set to show the rowcounts more intuitively)
You might be thinking that perhaps we no longer need the “FOR UPDATE” clause on the cursor, but it is still a required element. Without it, it is possible that a different session could update a row from the candidate data set, and that updated row would still be deleted. Or a different session could even delete, commit, and insert a fresh row that happens to pick up the same ROWID as one from the original set.
Bottom Line – keep concurrency front and foremost in your mind when you are writing code to manipulate data.
New option for configuring multipathing in Oracle Linux 7
Teaching is and remains the best way for picking up new things :) While updating notes for a class I came across an interesting change in the way the device-mapper multipath works in Oracle Linux 7.4.
In the past, everyone including me used scsi_id to get the WWID of a LUN for use with dm-multipath. This is still the way Oracle documents it for Oracle Linux 7.
The utility was specified as an argument to getuid_callout in /etc/multipath.conf, as shown here:
defaults {
[...]
getuid_callout "/lib/udev/scsi_id --whitelisted --device=/dev/%n"
[...]
}
This is how it was done more or less since Red Hat 5 days. The location of scsi_id has changed over time, as expertly described on Oracle Base for example.
I don’t exactly know what happened to getuid_callout, but I can’t find it in the DM Multipath documentation for Red Hat Enterprise Linux 7. It certainly is present in its counterpart for Red Hat Enterprise Linux 6. A quick search using my favourite search engine did not reveal any clues as to what happened. The closest I got to an answer was a page in the SLES 11 SP3 documentation, which indicated that you should use a different parameter than getuid_callout.
Now I was curious! If I continued using getuid_callout, would the service stop working? Or just throw a warning?
The experiment
I quickly spun up a VM on KVM, running Oracle Linux 7.4 which I updated to the latest and greatest version of each package as of April 3rd 2018. The current versions of dm-multipath as of April 3rd 2018 are:
[root@server6 ~]# rpm -qa | grep -i multipath device-mapper-multipath-0.4.9-111.el7_4.2.x86_64 device-mapper-multipath-libs-0.4.9-111.el7_4.2.x86_64 [root@server6 ~]#
I have presented a small “LUN” to the VM, using the virtual SCSI driver. I initially tried with the virtio driver but found it was not exporting necessary properties back to the VM that I need later in this post. It shouldn’t matter though, all of this is a playground and I am most interested in the concepts, not the details.
You will also notice that I am only showing snippets of the multipath.conf file. The reason for this is simple: if you don’t follow your storage vendor’s documentation detailing how to configure dm-multipath for the storage system in use, you might run into issues. Always consult your storage vendor’s official documentation!
Installing dm-multipath
I didn’t have multipathing installed initially and had to install it first. Here is the transcript:
[root@server6 ~]# yum install device-mapper-multipath [...] --> Running transaction check ---> Package boost-system.x86_64 0:1.53.0-27.el7 will be installed ---> Package boost-thread.x86_64 0:1.53.0-27.el7 will be installed --> Finished Dependency Resolution Dependencies Resolved ================================================================================================ Package Arch Version Repository Size ================================================================================================ Installing: device-mapper-multipath x86_64 0.4.9-111.el7_4.2 ol7_latest 134 k Installing for dependencies: boost-system x86_64 1.53.0-27.el7 ol7_latest 39 k boost-thread x86_64 1.53.0-27.el7 ol7_latest 57 k device-mapper-multipath-libs x86_64 0.4.9-111.el7_4.2 ol7_latest 251 k librados2 x86_64 1:0.94.5-2.el7 ol7_latest 1.7 M Updating for dependencies: kpartx x86_64 0.4.9-111.el7_4.2 ol7_latest 72 k Transaction Summary ================================================================================================ Install 1 Package (+4 Dependent packages) Upgrade ( 1 Dependent package) Total download size: 2.2 M [...] Running transaction check Running transaction test Transaction test succeeded Running transaction Installing : boost-system-1.53.0-27.el7.x86_64 1/7 Installing : boost-thread-1.53.0-27.el7.x86_64 2/7 Installing : 1:librados2-0.94.5-2.el7.x86_64 3/7 Installing : device-mapper-multipath-libs-0.4.9-111.el7_4.2.x86_64 4/7 Updating : kpartx-0.4.9-111.el7_4.2.x86_64 5/7 Installing : device-mapper-multipath-0.4.9-111.el7_4.2.x86_64 6/7 Cleanup : kpartx-0.4.9-111.el7.x86_64 7/7 Verifying : boost-system-1.53.0-27.el7.x86_64 1/7 Verifying : 1:librados2-0.94.5-2.el7.x86_64 2/7 Verifying : boost-thread-1.53.0-27.el7.x86_64 3/7 Verifying : device-mapper-multipath-0.4.9-111.el7_4.2.x86_64 4/7 Verifying : kpartx-0.4.9-111.el7_4.2.x86_64 5/7 Verifying : device-mapper-multipath-libs-0.4.9-111.el7_4.2.x86_64 6/7 Verifying : kpartx-0.4.9-111.el7.x86_64 7/7 Installed: device-mapper-multipath.x86_64 0:0.4.9-111.el7_4.2 Dependency Installed: boost-system.x86_64 0:1.53.0-27.el7 boost-thread.x86_64 0:1.53.0-27.el7 device-mapper-multipath-libs.x86_64 0:0.4.9-111.el7_4.2 librados2.x86_64 1:0.94.5-2.el7 Dependency Updated: kpartx.x86_64 0:0.4.9-111.el7_4.2 Complete! [root@server6 ~]#
First configuration attempt
Next I quickly created a config file based on what I used in the past, making sure I add getuid_callout in the defaults {} section. And sure enough, when starting the service it complains about illegal syntax:
[root@server6 ~]# systemctl status multipathd
● multipathd.service - Device-Mapper Multipath Device Controller
Loaded: loaded (/usr/lib/systemd/system/multipathd.service; enabled; vendor preset: enabled)
Active: active (running) since Tue 2018-04-03 14:56:19 BST; 1min 28s ago
Process: 586 ExecStart=/sbin/multipathd (code=exited, status=0/SUCCESS)
Process: 568 ExecStartPre=/sbin/multipath -A (code=exited, status=0/SUCCESS)
Process: 564 ExecStartPre=/sbin/modprobe dm-multipath (code=exited, status=0/SUCCESS)
Main PID: 596 (multipathd)
CGroup: /system.slice/multipathd.service
└─596 /sbin/multipathd
Apr 03 14:56:19 server6 systemd[1]: Starting Device-Mapper Multipath Device Controller...
Apr 03 14:56:19 server6 multipath[568]: Apr 03 14:56:19 | /etc/multipath.conf line 24, invalid keyword: getuid_callout
Apr 03 14:56:19 server6 systemd[1]: Started Device-Mapper Multipath Device Controller.
Apr 03 14:56:19 server6 multipathd[596]: /etc/multipath.conf line 24, invalid keyword: getuid_callout
Note the line reading “/etc/multipath.conf line 24, invalid keyword: getuid_callout”. It didn’t seem to prevent the meta-device from being created, but I didn’t like the error message popping up all the time.
After removing the getuid_callout from my multipath.conf file to let the defaults take over, the error went away after a restart of the service:
Apr 03 15:02:54 server6 systemd[1]: Stopped Device-Mapper Multipath Device Controller. Apr 03 15:10:43 server6 systemd[1]: Starting Device-Mapper Multipath Device Controller... Apr 03 15:10:43 server6 systemd[1]: Started Device-Mapper Multipath Device Controller. Apr 03 15:10:43 server6 multipathd[11593]: mpatha: load table [0 4194304 multipath 0 0 1 1 service-time 0 1 1 8:0 1] Apr 03 15:10:43 server6 multipathd[11593]: mpatha: event checker started Apr 03 15:10:43 server6 multipathd[11593]: path checkers start up
So I guess I have to rethink my approach to dm-multipath and device name persistence if I want to avoid this error message.
The New Way of doing things
I have once been told by a good friend: “when unsure, consult the documentation”. On my Linux system, my first stop is the man page. After a quick “man multipath.conf” I learned that getuid_callout is nowhere to be found. The SUSE note mentioned a new attribute, named uid_attribute, which seems to have taken its place:
- uid_attribute:
- The udev attribute providing a unique path identifier. Default value is ID_SERIAL
I also found this to be valuable about the “multipaths” section:
This section defines the multipath topologies. They are indexed by a World Wide Identifier (wwid), which is taken to be the value of the udev attribute given by the uid_attribute keyword.
Aha! The new model is potentially much more flexible than the old one.
Controlling aliases with multipath {} sections
I really like to assign alias names to LUNs mapped to my database systems. This way, I know that a device named “/dev/mapper/oracle_asm_data_001” is most likely used as the first ASM disk in disk group DATA. If I see /dev/mapper/mpatha instead, I know precisely nothing about its purpose.
Giving LUNs a name is not hard, you can do this in the multipaths {} section of /etc/multipath.conf. I really like doing this for reasons just mentioned. Which options do I have?
The easiest one is quite simply a change of getuid_callout to uid_attribute or its removal. Thankfully – at least in my case – the output of scsi_id and the ID_SERIAL attribute provided by udev are nearly identical:
[root@server6 ~]# /lib/udev/scsi_id --whitelisted --replace-whitespace --device=/dev/sda 0QEMU_QEMU_HARDDISK_drive-scsi0-0-0-0 [root@server6 ~]# udevadm info /dev/sda | grep ID_SERIAL E: ID_SERIAL=0QEMU_QEMU_HARDDISK_drive-scsi0-0-0-0 E: ID_SERIAL_SHORT=drive-scsi0-0-0-0 [root@server6 ~]#
Note that I included the –replace-whitespace option in the scsi_id command, otherwise the output wouldn’t be identical. This is a concession to my lab, on real hardware I haven’t seen white space in WWIDs (this doesn’t mean there aren’t). Removing the getuid_callout from the default {} section was actually enough to create a persistent device name.
[...]
multipaths {
multipath {
wwid "0QEMU_QEMU_HARDDISK_drive-scsi0-0-0-0"
alias "oracle_asm_data_001"
}
}
And yes, I get my alias after restarting the multipathing daemon.
Apr 03 16:40:49 server6 systemd[1]: Starting Device-Mapper Multipath Device Controller... Apr 03 16:40:49 server6 systemd[1]: Started Device-Mapper Multipath Device Controller. Apr 03 16:40:49 server6 multipathd[12271]: oracle_asm_data_001: load table [0 4194304 multipath 0 0 1 1 service-time 0 1 1 8:0 1] Apr 03 16:40:49 server6 multipathd[12271]: oracle_asm_data_001: event checker started Apr 03 16:40:49 server6 multipathd[12271]: path checkers start up [root@server6 ~]# multipath -l oracle_asm_data_001 (0QEMU_QEMU_HARDDISK_drive-scsi0-0-0-0) dm-3 QEMU ,QEMU HARDDISK size=2.0G features='0' hwhandler='0' wp=rw `-+- policy='service-time 0' prio=0 status=active `- 0:0:0:0 sda 8:0 active undef unknown [root@server6 ~]#
There is of course no second path, and there is a fair bit of information missing that your would otherwise get from an enterprise deployment, but you get the idea.
Answer: Anything Wrong With Query Performance? (Red Right Hand)
I of course attract a highly clever readership :). As some have commented, for a single table to require 1000+ consistent gets to retrieve 1000 rows implies that each row needs to be accessed from a different block. This in turn implies the Clustering Factor for this index to be relatively bad and the associated […]
exp catch
No-one should be using exp/imp to export and import data any more, they should be using the datapump equivalents expdp/impdp – but if you’re on an older (pre-12c) version of Oracle and still using exp/imp to do things like moving tables with their production statistics over to test systems then be careful that you don’t fall into an obsolescence trap when you finally upgrade to 12c (or Oracle 18).
exp/imp will mess up some of your histograms if you’re still using them to move tables/statistics in 12c.
Remember that 12c can create “Top-N” and “hybrid” histograms – and exp/imp were written long before these new histogram types came into existence. The code has not been updated to allow for the new histogram types so if you happen to generate any histograms of these type in a 12c system and then use exp/imp to move some table stats (and it’s particularly an issue relating to stats) from one system to another – the stats that arrive at the destination system won’t match the stats that left the source system.
Here’s a little sample code to build a model that I can use to demonstrate the problem. It creates a table with three columns that will make it easy for me to create one frequency histogram, one Top-N histogram and one hybrid histogram. I’ve included a couple of substitution variables in the code so that you can specify an Oracle instance to connect to and a directory for the export file that expdp is going to produce. Don’t forget to check that the directory I create in this script doesn’t overwrite a directory that already exists for other reasons on your test system.
rem
rem Script: 12c_histograms.sql
rem Author: Jonathan Lewis
rem Dated: Sep 2015
rem
rem Define m_service to be the service name you connect to
rem Define m_directory to be the O/S directory you to use for
rem the export/import/log files
rem
rem Make sure this code is not over-writing an existing
rem definition for a directory called DMPDIR before you
rem start
define m_service = 'orcl'
define m_service = 'or32'
define m_directory = '/mnt/working'
host rm &m_directory/expdat.dmp
host rm &m_directory/expdp.dmp
create or replace directory dmpdir as '&m_directory';
drop table t1 purge;
create table t1
nologging
as
with generator as (
select --+ materialize
rownum id
from dual
connect by
level <= 1e4 -- > comment to avoid wordpress format issue
)
select
trunc(sqrt(rownum + 0)) frequency,
trunc(sqrt(rownum + 0)) top_n,
trunc(sqrt(rownum + 0)) hybrid
from
generator
;
begin
dbms_stats.gather_table_stats(
ownname => user,
tabname =>'T1',
method_opt => 'for columns frequency size 254 for columns top_n size 95 for columns hybrid size 50'
);
end;
/
select
column_name,
num_distinct,
histogram,
num_buckets
from
user_tab_cols
where
table_name = 'T1'
;
column endpoint_actual_value format a22
break on column_name skip 1
select
column_name,
endpoint_number, endpoint_value, endpoint_actual_value,
endpoint_repeat_count
from
user_tab_histograms
where
table_name = 'T1'
order by
column_name, endpoint_number
;
Here’s an extract, from a 12.1.0.2 instance, of the results of the two queries with a large number of the rows from the histogram data deleted:
COLUMN_NAME Distinct HISTOGRAM Buckets
-------------------- ------------ --------------- ----------
FREQUENCY 100 FREQUENCY 100
TOP_N 100 TOP-FREQUENCY 95
HYBRID 100 HYBRID 50
COLUMN_NAME ENDPOINT_NUMBER ENDPOINT_VALUE ENDPOINT_ACTUAL_VALUE ENDPOINT_REPEAT_COUNT
-------------------- --------------- -------------- ---------------------- ---------------------
FREQUENCY 3 1 1 0
8 2 2 0
15 3 3 0
...
9800 98 98 0
9999 99 99 0
10000 100 100 0
HYBRID 3 1 1 3
224 14 14 29
440 20 20 41
...
9603 97 97 195
9800 98 98 197
10000 100 100 1
TOP_N 1 1 1 0
16 7 7 0
33 8 8 0
...
9753 98 98 0
9952 99 99 0
9953 100 100 0
The most important detail is the endpoint_repeat_count column of the hybrid histogram, although you should note that the endpoint_actual_value columns is populated with a copy of the endpoint_value for all three histograms.
Now I’m going to use exp / drop table / imp (or the datapump equivalents) to export, drop, and re-import the table with (one hopes) the exact same statistics. To do this I’ll be using the imp command with the option “statistics=always” with the intention of copying the stats from the export file into the destination database (you’ll have to substitute your own userid/password, of course):
host exp userid=test_user/test@&m_service file=expdat.dmp tables='(t1)' -- host expdp userid=test_user/test@&m_service DIRECTORY=dmpdir DUMPFILE=expdp.dmp TABLES='(t1)' drop table t1 purge; host imp userid=test_user/test@&m_service file=expdat.dmp tables='(t1)' statistics=always -- host impdp userid=test_user/test@&m_service DIRECTORY=dmpdir DUMPFILE=expdp.dmp TABLES='(t1)'
So what do we see now when we re-run the two queries to report the histogram information:
COLUMN_NAME Distinct HISTOGRAM Buckets
-------------------- ------------ --------------- ----------
FREQUENCY 100 FREQUENCY 100
TOP_N 100 FREQUENCY 95
HYBRID 100 FREQUENCY 50
COLUMN_NAME ENDPOINT_NUMBER ENDPOINT_VALUE ENDPOINT_ACTUAL_VALUE ENDPOINT_REPEAT_COUNT
-------------------- --------------- -------------- ---------------------- ---------------------
FREQUENCY 3 1 0
8 2 0
15 3 0
...
9800 98 0
9999 99 0
10000 100 0
HYBRID 3 1 0
224 14 0
440 20 0
...
9603 97 0
9800 98 0
10000 100 0
TOP_N 1 1 0
16 7 0
33 8 0
...
9753 98 0
9952 99 0
9953 100 0
The histograms on all three columns are now labelled as FREQUENCY.
The endpoint_actual_value is null for all three – but that may be a purely cosmetic detail with no side effects.
The “hybrid” column really has become a frequency histogram – and that’s the critical one – the endpoint_repeat_count columns are all zero.
tl;dr
If you’re still using exp/imp instead of expdp/impdp to move tables (and, more importantly, their statistics) from one database to another then the upgrade to 12c may mean you end up with hybrid histograms on the source system that are “downgraded” to frequency histograms on the destination system, with the effect that execution plans vary between the two systems.
A look into oracle redo, part 9a: commit – concurrency considerations
During the investigations of my previous blogpost about what happens during a commit and when the data becomes available, I used breaks in gdb (GNU debugger) at various places of the execution of an insert and a commit to see what is visible for other sessions during the various stages of execution of the commit.
However, I did find something else, which is very logical, but is easily overlooked: at certain moments access to the table is blocked/serialised in order to let a session make changes to blocks belonging to the table, or peripheral blocks like undo, for the sake of consistency. These are changes made at the physical layer of an Oracle segment, the logical model of Oracle says that writers don’t block readers.
The first question is if this is a big issue. Well, for that you should simply look at any normal usage of an Oracle database. I don’t believe these serialisation moments are an issue, because the majority of my client’s does not experience serialisation problem.
However, this can become an issue if database processes can not run at will. What that means is that if processes are randomly stopped from execution by the operating system or hypervisor, it could be that the database process can be at an earlier mentioned ‘serialisation point’, which then means that access for all other processes remains blocked until the process is made running again, which then gives the process the opportunity to free exclusive access to a resource.
What are issues when a database process can not run at will?
– CPU oversubscription. If more processes are running than CPU’s are available (think about core’s and threads, and what it means for your CPU architecture), it means the operating system needs to make a decision on what it wants to be running, and what it wants to wait. No operating system scheduler understands or can know when an Oracle database process is running in a critical part of code, and therefore should not stop execution of it.
– Memory oversubscription. Whenever your system starts actively swapping in and out, your system is swapping, which means it’s moving active pages onto the swap device, and reads back active pages from the swap device for a process that demands them. This will activate additional tasks, and make processes get stuck waiting for memory to become available at all kinds of points during execution. Often, swapping is the beginning of the end, which means the services on the server stop functioning altogether for multiple reasons, like the Out Of Memory killer, or simply timing out for client’s of a process.
– Oversubscription of CPU or memory using virtualisation. As a troubleshooter, I would say this is actually worse than the ‘simple oversubscription’ mentioned in the two earlier points. Because typically, the visible part is the virtual machine. The virtual machine in this case itself is not oversubscribed, the oversubscription takes place at a layer invisible to the virtual machine, which unexplainably performs unpredictable. It is simply not okay to oversubscribe any machine that needs to run something that is latency sensitive like the Oracle database, unless you fully understand all the trade-offs that are coming with it, and you have the ability to understand when it does start to occur.
Whenever database processes can not run at will, you will see waits you didn’t see when processes could run at will. Typical waits in that case are (not an exhaustive list):
– any latch waits
– buffer busy waits
– any cursor: pin waits
Please mind these waits are not unique for this issue, any of these waits can occur for other reasons too.
Let me show a couple of examples for which the wait is artificially created by stopping execution at a point where this serialisation takes place, thereby mimicking getting put off cpu due to load, using the earlier insert and commit execution:
a) latch: cache buffers chains
Whenever a process needs to read or modify a database buffer, it needs to ‘pin’ the buffer. Such a pin is also known as a buffer handle or a buffer state object. The pin, which is a memory area, must be obtained from a freelist and attached to the buffer header in order to pin the buffer. A pin is obtained using the kcbzgs (kernel cache buffers helper functions get state object) function, which calls the kssadf_numa_intl (kernel service state objects add from freelist numa internal) function which initialises the state object.
The function that performs the actual pin of a block is not a single one, pinning a block is done in multiple functions. Two of them are kcbgtcr (kernel cache buffers get consistent read) and kcbgcur (kernel cache buffers get current). Under normal circumstances, concurrency for a consistent read of a buffer (kcbgtcr) does not lead to any blocking, because the latch (cache buffers chains) can be taken in shared mode, and the pinning is done in ‘fast mode’ (my interpretation):
> kcbgtcr(0x7f88a8b79db0, 0, ...) | > kscn_to_ub8_impl(0x7f88a8b88d4c, 0x6baefdc0, ...) | < kscn_to_ub8_impl+0x00000000003e returns: 0x287562 | > ktrexf(0x7fff998123f8, 0x7f88ae5d7f30, ...) | | > ktrEvalBlockForCR(0x7f88a8b88d4c, 0x7f88ae5d7f30, ...) | | < ktrEvalBlockForCR+0x0000000000f4 returns: 0x1 | < ktrexf+0x0000000000a4 returns: 0x9 | > kcbzgsf(0x1, 0x7fff998120b8, ...) | | > kssadf_numa_intl(0x36, 0x6ddc0b50, ...) | | | > kpdbIdToUid(0, 0x6ddc0b50, ...) | | | < kpdbIdToUid+0x0000000000e7 returns: 0 | | < kssadf_numa_intl+0x000000000235 returns: 0x6bf84908 | < kcbzgsf+0x0000000001a0 returns: 0x6bf84908 | > kcbz_fp_cr(0x8dff9478, 0x6bf84998, ...) | < kcbz_fp_cr+0x000000000089 returns: 0 | > kscn_to_ub8_impl(0x7f88a8b88d70, 0x1, ...) | < kscn_to_ub8_impl+0x00000000003e returns: 0 < kcbgtcr+0x000000000b38 returns: 0x8df94014
Inside the kcbgtcr function, kcbzgsf (kernel cache buffers helper functions test state object fast) is called, and after that, the state object is pinned to the block in kcbz_fp_cr (kernel cache buffers helper functions fast pin for consistent read). Do you see the absence of ksl_get_shared_latch function to serialise access to add this pin? Actually the cache buffers chains latch is gotten, but it’s done inside the kcbgtcr function. The latch is gotten before the ktrexf (kernel transaction redo examine block fast) in shared mode, and the latch is released after the kcbz_fp_cr function. Multiple processes can pin the block for consistent read without serialisation or blocking each other because of the cache buffers chains latch being a shared latch, and this latch is taken in shared mode.
Why do I show this? Well, in the “old” days, which is Oracle 8.1, Oracle did not use shared latches (at least on the platforms I worked on, but if my memory serves me right, shared latches were introduced starting from Oracle 9), which meant for any logical read the cache buffers chains latch had to be obtained. This could get painful for very frequently visited blocks, like index root blocks, and high concurrency, and additional to that, because there was no post/wait messaging for latch waits but only spinning, this meant lots of processes waiting for latch number 98, and CPU usage going through the roof.
Back to today. Below is shown how the function calls look like when DML is done. When a buffer change is done (data is changed), a buffer has to be obtained in current mode, which is done using the kcbgcur function:
> kcbgcur(0x7ffda5957c70, 0x2, ...) | > kcbzgs(0x1, 0x2, ...) | | > kssadf_numa_intl(0x36, 0x7a6086c8, ...) | | | > kpdbIdToUid(0, 0x7a6086c8, ...) | | | < kpdbIdToUid+0x0000000000e7 returns: 0 | | < kssadf_numa_intl+0x000000000235 returns: 0x7867c9c0 | < kcbzgs+0x000000000178 returns: 0x7867c9c0 | > kti_is_imu(0x7867ca50, 0xb0f71018, ...) | | > ktcgtx(0x76f29d50, 0xb0f71018, ...) | | < ktcgtx+0x00000000001e returns: 0x76f29d50 | < kti_is_imu+0x000000000039 returns: 0 < kcbgcur+0x0000000009fb returns: 0xb0302014
This looks reasonably the same as the previous call overview which shown kcbgtcr, however the kcbzgsf function changed to kcbzgs, so minus the ‘f’ for fast, and a few other functions are missing. Another interesting thing (not visible) is the cache buffers chains latch is obtained after the kcbzgs function that obtains the buffer state object, and the latch is obtained with special bit 0x1000000000000000 set to indicate the shared latch is obtained in non-shared mode. After the kti_is_imu function the pin is attached to the buffer and the latch is freed.
To make things a little more complicated, a buffer can be gotten in current mode, but still get the cache buffers chains in shared mode. This is how that looks like:
> kcbgcur(0x7ffda5955620, 0x1, ...) | > kcbzgs(0x1, 0x1, ...) | | > kssadf_numa_intl(0x36, 0x7a6086c8, ...) | | | > kpdbIdToUid(0, 0x7a6086c8, ...) | | | < kpdbIdToUid+0x0000000000e7 returns: 0 | | < kssadf_numa_intl+0x000000000235 returns: 0x7867c9c0 | < kcbzgs+0x000000000178 returns: 0x7867c9c0 | > kcbz_fp_shr(0xb0fa3cb8, 0x7867ca50, ...) | < kcbz_fp_shr+0x000000000085 returns: 0x7f3011d82f40 < kcbgcur+0x0000000009fb returns: 0xb07a0014
The function kcbzgs without ‘f’ is called, but the cache buffers chains latch is gotten in shared mode (not visible; done in the kcbgcur function after kcbzgs), and there’s the function kcbz_fp_shr (kernel cache buffers helper function fast pin shared) to pin the buffer in shared mode.
In order to be allowed to change a buffer, the cache buffers chains latch must be taken in non-shared mode to change the buffer header to indicate the buffer is busy and guarantee only the process itself can access it. Obtaining the cache buffers chains latch in non-shared mode means that access to the hash bucket (multiple hash buckets actually) to which the buffer is linked is blocked until the latch is freed. Please mind the period that the latch is obtained here is very short.
However, this blocking scenario can be easily replayed:
1. session 1: startup a database foreground session.
2. session 2: obtain the PID of the session 1’s process and attach to it with gdb.
3. session 2: break on the kti_is_imu function (break kti_is_imu) and continue.
4. session 1: insert a row into a table (insert into test values (‘a’);). the breakpoint will fire in gdb, stopping execution.
5. session 3: startup another database foreground session.
6. session 3: select the table on which the insert just broke (select * from test;). This will hang.
7. session 4: startup a SYSDBA session, and obtain the wait state of the foreground sessions:
SQL> @who active SID_SERIAL_INST OSPID USERNAME C SERVER PROGRAM EXTRA --------------- -------- ------------- - --------- ------------------------------------------------ ------------- 59,53450,@1 28166 SYS * DEDICATED sqlplus@memory-presentation.local (TNS V1-V3) time:0ms,event:ON CPU:SQL,seq#:98 102,53150,@1 28083 TS DEDICATED sqlplus@memory-presentation.local (TNS V1-V3) time:66867.83ms,event:ON CPU:SQL,seq#:33 101,6637,@1 28186 TS DEDICATED sqlplus@memory-presentation.local (TNS V1-V3) time:344013.82ms,event:latch: cache buffers chainsp1:1811473056p2:289p3:24599> Blocked by (inst:sid): 1:102,seq#:39
SID 101 is waiting on the cache buffers chains latch, because SID 102 is holding that. SID 102 is showing ON CPU because we broke execution outside of a wait event, so Oracle thinks it’s busy executing, while it is actually stopped by gdb.
Again, this is a wait (latch: cache buffers chains) that is unlikely be an issue, and if it is, you either ran into a bug, or this is only the way a much bigger problem (oversubscription, bad application design) is showing itself.
b) buffer busy waits
The name of the wait event ‘buffer busy wait’ is self explanatory. The technical implementation is way lesser known. What technically happens during a buffer busy wait, is that a session needs to read a certain buffer, and in order to read it, it performs the usual actions of selecting the correct cache buffers chains bucket, following the double linked list to the buffer headers to find the best best buffer and then obtain a buffer state object. The critical part for running into the buffer busy wait is when the session checks the state of the buffer via the buffer header and finds the change state (X$BH.CSTATE) to be higher than 0, indicating the block is currently being changed. At this point the session calls kcbzwb (kernel cache buffers helper function wait for buffer), and must wait for the buffer state to be changed and therefore accessible, for which the wait event is the buffer busy wait event. When the change state is reverted back to 0, the buffer is accessible again.
Once a buffer is pinned in current mode using kcbgcur en kcbzgs, the buffer is still fully accessible for all sessions. Only once the database truly starts to change the buffer, which is done in kcbchg1_main, the cache buffers chains latch is taken non-shared, and the CSTATE field in the buffer header is changed to 1 and then the latch is freed. My current investigations show that the CSTATE is changed to 2 after the kcopcv and kcrfw_copy_cv functions, so when the redo is written to the public redo strand, and set to 4 after the changes have been written to the buffers, which is done in kcbapl. At the end of the kcbchg1_main function, when all the changes are done, the cache buffers chains latch is taken non-shared again, the CSTATE field is set to 0 and the latch is freed to enable access to the buffer again.
68801:kcbchg1_main+2536:0x000000006ba4e4d8(Variable Size(pgsz:2048k)|+182772952 shared pool|(child)latch#5383:cache buffers chains+0 shared pool|permanent memor,duration 1,cls perm+2204888 ):R:8:0/0() 68802:kcbchg1_main+2536:0x000000006ba4e4d8(Variable Size(pgsz:2048k)|+182772952 shared pool|(child)latch#5383:cache buffers chains+0 shared pool|permanent memor,duration 1,cls perm+2204888 ):W:8:0x1000000000000022/1152921504606847010() .. 68897:kcbchg1_main+3318:0x00000000967eddda(Variable Size(pgsz:2048k)|+901701082 buffer header|9668A000+66 ):W:1:0x1/1() .. 68939:kcbchg1_main+3715:0x000000006ba4e4d8(Variable Size(pgsz:2048k)|+182772952 shared pool|(child)latch#5383:cache buffers chains+0 shared pool|permanent memor,duration 1,cls perm+2204888 ):R:8:0x1000000000000022/1152921504606847010() 68940:kcbchg1_main+3715:0x000000006ba4e4d8(Variable Size(pgsz:2048k)|+182772952 shared pool|(child)latch#5383:cache buffers chains+0 shared pool|permanent memor,duration 1,cls perm+2204888 ):W:8:0/0()
Above you see a cache buffers chains latch being obtained non shared (special bit 0x1000000000000000 is set), a little later the buffer header is updated which sets the value 1 at offset 66. Once this happens, this is visible in the CSTATE column of X$BH. A little further the latch is freed.
Why am I showing all of this? Well, there is quite some work that is done while the buffer is in a changed state (CSTATE>0) and therefore inaccessible. In normal situations, this is not a problem because despite all the work this is done very quickly, and therefore it’s hardly noticeable/measurable, so there’s no or very little time spend in buffer busy waits in most databases
However… if processes do get stuck randomly, it’s possible that a process gets stuck while making changes to a buffer, which then means any additional access to the buffer results in buffer busy waits. Also mind that a change to a table buffer requires (at least; in the most simple case) three buffers to be changed: the buffer containing the table data, the buffer containing the undo segment transaction table and the buffer containing the actual undo. A commit requires one buffer: the undo segment transaction table.
Let me show you an example:
1. session 1: startup a database foreground session.
2. session 2: obtain the PID of the session 1’s process and attach to it with gdb.
3. session 2: break on ktugur and kcopcv and continue.
4. session 3: startup a database foreground session.
5. session 1: insert a row into a table: insert into test values (‘a’);
6. session 2: gdb breaks execution of session 1 because it encountered ktugur.
7. session 3: select * from test; this runs unblocked.
8. session 4: startup a database foreground session as sysdba.
9. session 4: select * from v$lock; this will hang.
This one wasn’t obvious. I found this upon doing the tests. When a foreground session is in ktugur, it is creating the change vectors (kernel transaction undo generate undo and redo), and it holds two buffers in current mode:
SQL> l 1 select ts.name tablespace, 2 dbablk, 3 class, 4 state, 5 decode(state,0,'free',1,'xcur',2,'scur',3,'cr', 4,'read',5,'mrec',6,'irec',7,'write',8,'pi', 9,'memory',10,'mwrite',11,'donated', 12,'protected', 13,'securefile', 14,'siop',15,'recckpt', 16, 'flashfree', 17, 'flashcur', 18, 'flashna') state_decoded, 6 mode_held, 7 changes, 8 cstate, 9 flag, 10 flag2, 11 rflag, 12 sflag, 13 lru_flag, 14 dirty_queue 15 from x$bh b 16 , v$tablespace ts 17 where 1=1 18 and not (us_nxt = us_prv and wa_nxt = wa_prv and to_number(wa_nxt,'xxxxxxxxxxxxxxxx') = to_number(us_nxt,'xxxxxxxxxxxxxxxx') + 16) 19* and b.ts#=ts.ts# SQL> / TABLESPACE DBABLK CLASS STATE STATE_DECO MODE_HELD CHANGES CSTATE FLAG FLAG2 RFLAG SFLAG LRU_FLAG DIRTY_QUEUE ------------------------------ ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ----------- UNDOTBS1 128 17 1 xcur 2 1 0 2097152 0 0 0 0 0 TS 24597 1 1 xcur 2 1 0 2097153 0 0 0 0 0
The thing that was not obvious at first was that the blocks have CSTATE 0; so they can be accessed and read for a consistent read. Then I look at the wait and the p1/2/3 of the wait:
SID_SERIAL_INST OSPID USERNAME C SERVER PROGRAM EXTRA --------------- -------- ------------- - --------- ------------------------------------------------ ------------------------------------------------------- 100,262,@1 6274 SYS DEDICATED sqlplus@memory-presentation.local (TNS V1-V3) time:2519.48ms,event:buffer busy waitsp1:3p2:128p3:17> Blocked by (inst:sid): 1:59,seq#:476 142,15103,@1 6695 TS DEDICATED sqlplus@memory-presentation.local (TNS V1-V3) time:47115.23ms,event:SQL*Net message from client,seq#:226 12,25165,@1 7036 SYS * DEDICATED sqlplus@memory-presentation.local (TNS V1-V3) time:0ms,event:ON CPU:SQL,seq#:3165 59,31601,@1 5891 TS DEDICATED sqlplus@memory-presentation.local (TNS V1-V3) time:31292.51ms,event:ON CPU:SQL,seq#:111
Above SID 100 is session 4; it hangs on a buffer busy wait. The datafile is #2, which is the undo table space UNDOTBS1 and the buffer that it is waiting for is 128. Why does SID 100 needs to wait for the buffer, while another session (session 3 in the above runbook) can run without getting blocked for a buffer that is held exactly in the same state (xcur and CSTATE is zero)?
The answer can be gotten when executing pstack on the waiting process (or attach with gdb and obtain a backtrace):
(gdb) bt #0 0x00007fd6a085bbda in semtimedop () at ../sysdeps/unix/syscall-template.S:81 #1 0x0000000010f9cca6 in sskgpwwait () #2 0x0000000010f9a2e8 in skgpwwait () #3 0x0000000010a66995 in ksliwat () #4 0x0000000010a65d25 in kslwaitctx () #5 0x00000000015c5e5e in kcbzwb () #6 0x0000000010b3748e in kcbgcur () #7 0x0000000010ab9b17 in ktuGetUsegHdr () #8 0x00000000014075d3 in ktcxbcProcessInPDB () #9 0x0000000001406de2 in ktcxbc () #10 0x0000000010ea8781 in qerfxFetch () #11 0x0000000010bb919c in rwsfcd () #12 0x00000000035ae618 in qeruaFetch () #13 0x00000000035ad837 in qervwFetch () #14 0x0000000010bb919c in rwsfcd () #15 0x0000000010ea1528 in qerhnFetch () #16 0x0000000010bb919c in rwsfcd () #17 0x0000000010ea1528 in qerhnFetch () #18 0x0000000010c9eeb3 in opifch2 () #19 0x000000000268c3de in kpoal8 () #20 0x0000000010ca5b3d in opiodr () #21 0x0000000010f37a29 in ttcpip () #22 0x0000000001eb4674 in opitsk () #23 0x0000000001eb914d in opiino () #24 0x0000000010ca5b3d in opiodr () #25 0x0000000001eb04ed in opidrv () #26 0x0000000002afedf1 in sou2o () #27 0x0000000000d05577 in opimai_real () #28 0x0000000002b09b31 in ssthrdmain () #29 0x0000000000d05386 in main ()
The important bit is at #6: kcbgcur (kernel cache buffers get buffer in current mode)! In other words: the block is gotten in current mode while another session is holding the block in current mode, which means it has to wait. The function kcbzwb means kernel cache buffer helper function wait for buffer.
I really wondered why the undo segment buffer is gotten in current mode; this is a read, there is no intention to change something. The current educated guess is this a way to be sure this buffer contains the current state of the transactions across all nodes in a RAC cluster. So this might be a clever optimisation to be absolutely sure the current state of the undo segment transaction table is gotten.
10. session 2: continue. This will break on kcopcv.
11. session 3: select * from test; this will hang.
Now we have two hanging sessions waiting for the wait event buffer busy wait:
SQL> @who active SID_SERIAL_INST OSPID USERNAME C SERVER PROGRAM EXTRA --------------- -------- ------------- - --------- ------------------------------------------------ ----------------- 100,262,@1 6274 SYS DEDICATED sqlplus@memory-presentation.local (TNS V1-V3) time:120790ms,event:buffer busy waitsp1:3p2:128p3:35> Blocked by (inst:sid): 1:59,seq#:501 142,15103,@1 6695 TS DEDICATED sqlplus@memory-presentation.local (TNS V1-V3) time:1175715.03ms,event:buffer busy waitsp1:4p2:24597p3:1> Blocked by (inst:sid): 1:59,seq#:250 12,25165,@1 7036 SYS * DEDICATED sqlplus@memory-presentation.local (TNS V1-V3) time:0ms,event:ON CPU:SQL,seq#:3309 59,31601,@1 5891 TS DEDICATED sqlplus@memory-presentation.local (TNS V1-V3) time:9544.97ms,event:ON CPU:SQL,seq#:116
SID 100 still hangs in wait event buffer busy wait for file 3, block 128, but now the session doing the full table scan also hangs in wait event buffer busy wait, but for file 4, block 24597. Let’s look at the buffers held in current mode again:
SQL> @pinned_blocks TABLESPACE DBABLK CLASS STATE STATE_DECO MODE_HELD CHANGES CSTATE FLAG FLAG2 RFLAG SFLAG LRU_FLAG DIRTY_QUEUE ------------------------------ ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ----------- UNDOTBS1 128 35 1 xcur 2 0 1 2097156 0 0 0 0 0 UNDOTBS1 3127 36 1 xcur 2 0 1 2097156 0 0 0 0 0 TS 24597 1 1 xcur 2 0 1 2097157 0 0 0 0 0
Because the insert progressed to kcopcv, the CSTATE of all three buffers involved in the insert, the undo segment transaction table, the undo segment undo entry and the buffer which has the inserted row are set to 1. This means that the two buffer busy waits are actually two different reasons: the select * from v$lock still waits to get a buffer in current mode, and the select * from test, which does a consistent read, now is waiting for the CSTATE to get set back to 0. In order to solve the hanging, go to session 2 and continue. This will break again on kcoapl, and again if you continue, because there are 3 blocks involved in this insert. Another way to make the insert finish is to disable all breakpoints (disable command) or to quit gdb.
Just for the fun of it, here is another example of how a stuck session can escalate: a process that gets stuck executing the kcbapl (kernel cache buffers apply a change to a buffer). This scenario can be replayed using the following steps:
1. session 1: startup a database foreground session.
2. session 2: obtain the PID of the session 1’s process and attach to it with gdb.
3. session 2: break on kcbapl and continue.
4. session 3: startup a database foreground session.
5. session 3: insert a row into a table: insert into test values (‘a’);
6. session 1: insert a row into a table: insert into test values (‘a’);
7. session 2: gdb broken execution of session 1 because it encountered kcbapl.
8. session 3: commit; this will hang
Can you reason why session 3 is hanging? Both the sessions are doing inserts to the same table…Give it a thought and replay it yourself.
Explanation: the breakpoint stopped execution before actually doing the changes. CSTATE for the buffer is set to 1, it will get set to 2 inside kcbapl to indicate the change vectors have been copied. But the important bit is that a redo copy latch was taken before executing kcbapl. The commit in session 3 sent a message to the logwriter asynchronously asking it to write (first invocation of kcrf_commit_force_int), and then freed the logical locking of the insert, and then invoked kcrf_commit_force again to wait for the logwriter to finish writing and get notified. However, the logwriter needs to obtain all the redo copy latches (it actually reads a metadata structure that indicates the redo copy latches are freed or not), at which it needs to wait because session 1 stuck holding a redo copy latch and therefore needs to wait. Not only does this show how dangerous it is when sessions can’t run, it also shows how dangerous it can be to run gdb in a production database, it can be quite hard to figure out what will be the implication of attaching with gdb to the process. So the actual outcome of above is that session 3 waits in the event ‘log file sync’, and the logwriter is waiting in ‘LGWR wait for redo copy’.
Summary
The Oracle database is carefully setup to be able to handle concurrency. In most normal situations you will see no to maybe very little time spend in wait events that indicate concurrency, like latches or buffer busy waits. If an Oracle database is on a machine that has more active processes than available CPU threads or cores (this depends on the hardware and CPU architecture; for Intel based architectures you should lean towards core’s, for SPARC you can lean more towards threads), the operating system needs to make choices, and will do that trying to give all processes an equal share. This means that processes will be put off CPU in order to give all processes a fair share of CPU run time. Also mind other oversubscription possibilities, like using more memory than physically available, and doing the same using virtualisation, which is handing out more VCPU’s than CPU threads, and handing out more memory than physically available. Because you can’t look outside your virtual machine, it’s often harder to troubleshoot virtualisation oversubscription issues.
Oracle really tries to minimise the amount of time spend while holding a non shared latch. Therefore with modern Oracle databases it’s unlikely that latch waits show up, even if a system is (not too much) oversubscribed. If you do have a latching problem, it’s most likely you have got another problem which causes this.
The most well documented reason for buffer busy waits is a buffer being written onto persistent media, and therefore the buffer is marked busy for the time of the write. Another reason that is documented, is getting a buffer in a mode that is not compatible with the mode it is held in. Having a buffer in current mode will block another request for the buffer in current mode. But, having a buffer pinned in current mode does not block consistent read access, it’s only when the buffer is being changed that requires the buffer to be marked busy. This state is externalised in the CSTATE column of the view X$BH, which shows fields of the buffer header struct that is used to manage the buffer cache buffers. Because there is quite some work to be done when a buffer is changed, and during making these changes the buffers are not usable (‘busy’) for other processes, a buffer busy wait is more likely to occur when oversubscription is taking place.
Thanks to Jonathan Lewis for explaining how to get the buffer header addresses.
Thanks to Abel Macias for brainstorming.
Data Hashing
Here’s a little-known feature that has been around since at least Oracle 10, though I don’t think I had ever seen it in the wild until today when someone reported on the ODC (OTN) database forum that they had a problem getting repeatable results. It’s always possible, of course, that failure to get repeatable results is the natural consequence of running queries against a multi-user system, but if we assume that this was not the cause in this case we have to ask why a special hashing function that Oracle supplies to allow you to check that a set of data hasn’t changed gives you different results when “the data hasn’t changed”.
I’m talking about the function dbms_sqlhash.gethash() – a packaged function that exists in the SYS schema and isn’t usually exposed to other users. The function takes as its inputs the text of query, a selected hashing function, and a “chunk” size. It will run the query, and use the hashing function to return a single, 16 – 64 byte, hash value representing the entire result set. Here’s an example of usage:
begin
dbms_output.put_line(
dbms_sqlhash.gethash(
sqltext => 'select n1, d1 from t1 where id > 0',
digest_type => dbms_crypto.hash_md5
-- chunk_size => 128*1048576 -- default 128MB
)
);
end;
/
6496D2438FECA960B1E916BF8C4BADCA
I haven’t specified a chunk size – the default is 128MB – and Oracle will hash this much of the result set in a single pass. If the result set is larger than this Oracle will hash each chunk in turn then generate a hash of the hash values. (This means, by the way, that changing the chunk size can change the hash value for large data sets).
There are 6 possible digest types in 12.1.0.2 (listed in the $ORACLE_HOME/rdbms/admin/dbmsobtk.sql script that creates the dbms_crypto package – so you will need the execute privilege on both dbms_sqlhash and dbms_crypto to use the function if you want to code with symbolic constants):
rem HASH_MD4 CONSTANT PLS_INTEGER := 1; rem HASH_MD5 CONSTANT PLS_INTEGER := 2; rem HASH_SH1 CONSTANT PLS_INTEGER := 3; rem HASH_SH256 CONSTANT PLS_INTEGER := 4; rem HASH_SH384 CONSTANT PLS_INTEGER := 5; rem HASH_SH512 CONSTANT PLS_INTEGER := 6;
Let’s put the whole thing into a demonstration that will allow us to see an important point – you have to be careful with your query:
rem
rem Script: gethash.sql
rem Author: Jonathan Lewis
rem Dated: Feb 2016
rem
execute dbms_random.seed(0)
create table t1
nologging
as
select
1e4 - rownum id,
trunc(dbms_random.value(0,100)) n1,
trunc(sysdate) d1,
lpad('x',100,'x') padding
from
dual
connect by
level <= 1e4 -- > comment to avoid WordPress format issue
;
alter table t1 add constraint t1_pk primary key (id);
begin
dbms_stats.gather_table_stats(
ownname => user,
tabname => 'T1',
method_opt => 'for all columns size 1'
);
end;
/
set feedback off
alter system flush shared_pool;
alter session set optimizer_mode = first_rows_1;
begin
dbms_output.put_line(
dbms_sqlhash.gethash(
sqltext => 'select n1, d1 from t1 where id > 0',
digest_type => dbms_crypto.hash_md5
-- chunk_size => 128*1048576 -- default 128MB
)
);
end;
/
alter system flush shared_pool;
alter session set optimizer_mode = all_rows;
begin
dbms_output.put_line(
dbms_sqlhash.gethash(
sqltext => 'select n1, d1 from t1 where id > 0',
digest_type => dbms_crypto.hash_md5
-- chunk_size => 128*1048576 -- default 128MB
)
);
end;
/
alter system flush shared_pool;
alter session set nls_date_format='dd-mon-yyyy hh24:mi:ss';
begin
dbms_output.put_line(
dbms_sqlhash.gethash(
sqltext => 'select n1, d1 from t1 where id > 0',
digest_type => dbms_crypto.hash_md5
-- chunk_size => 128*1048576 -- default 128MB
)
);
end;
/
alter session set nls_date_format='DD-MON-RR';
I’ve created a data set, added a primary key, and gathered stats, then I’ve called the same hashing function on the same sql statement three times in a row. However, I’ve changed the session environment for each call – in the first case I’ve set the optimizer to “first rows(1)” optimization, then I’ve set the optimizer back to all_rows, then I’ve changed the nls_date_format from its default of “DD-MON-RR” (and that’s significant because I’ve got a date column in my query). Here are the output from running the script:
Table created. Table altered. PL/SQL procedure successfully completed. 6496D2438FECA960B1E916BF8C4BADCA D41D4A2945D0B89A6C5DEB5060189A54 ECC3D2B66CB61821397CD9BD983FD5F4
The query has to return the same data content in all three cases – but the hash value is different in the three cases. The change in the optimizer mode has affected the order in which the data was returned (with first_rows(1) Oracle did a full scan of the primary key index, with all_rows it did a tablescan and sort); the change in the nls_XXX parameter meant the internal representation of the data changed.
You have to be very careful with dbms_sqlhash every time you use it if you want the same data set to produce the same result. First, to be safe, you need to ensure that you always use the same NLS parameters when using the function; then you need to have an “order by” clause in the query, and the columns used in the order by clause need to a possible candidate key (i.e. unique, not null) for the data otherwise a change in the optimizer parameters, or the object stats, could result in a change in execution plan with an ensuing change in the actual order of the data and a different hash value.
Speaking At DOAG 2018 Exa & Middleware Days In Frankfurt
I will be speaking at the DOAG 2018 Exa & Middleware Days in Frankfurt on June 18th and 19th. My talk will be "Exadata & InMemory Real World Performance" where I discuss the different performance improvements you can expect from the super fast scans delivered by those technologies depending on the actual work profile of the SQL and data used.
Hope to see you there!
SQL Monitor
I’ve mentioned the SQL Monitor report from time to time as a very useful way of reviewing execution plans – the feature is automatically enabled by parallel execution and by queries that are expected to take more than a few seconds to complete, and the inherent overheads of monitoring are less than the impact of enabling the rowsource execution statistics that allow you to use the ‘allstats’ format of dbms_xplan.display_cursor() to get detailed execution information for a query. The drawback to the SQL Monitor feature is that it doesn’t report predicate information. It’s also important to note that it falls under the performance and diagnostic licences: some of the available performance informtion comes from v$active_session_history, and the report is generated by a call to the dbms_sqltune package.
There are two basic calls – report_sql_monitor_list(), which appeared in 11.2, produces a summary of the statements and their individual executions (from the information that is still in memory, of course) and report_sql_monitor() shows detailed execution plans. Here’s a simple bit of SQL*Plus code showing basic use – it lists a summary of all the statements monitored in the last half hour, then (as it stands at present) the full monitoring details of the most recently completed monitored statement:
set long 250000
set longchunksize 65536
set linesize 254
set pagesize 100
set trimspool on
set heading off
column text_line format a254
spool report_sql_monitor
select
dbms_sqltune.report_sql_monitor_list(
active_since_date => sysdate - 30 / (24*60),
type => 'TEXT'
) text_line
from dual
;
select
dbms_sqltune.report_sql_monitor(
-- sql_id => '&m_sql_id',
-- start_time_filter => sysdate - 30/(24 * 60),
-- sql_exec_id => &m_exec_id,
type =>'TEXT'
) text_line
from dual
;
spool off
Here’s a variation that reports the details of the most recently completed execution of a query with the specified SQL_ID:
set linesize 255
set pagesize 200
set trimspool on
set long 200000
column text_line format a254
set heading off
define m_sql_id = 'fssk2xabr717j'
spool rep_mon
SELECT dbms_sqltune.report_sql_monitor(
sql_id=> v.sql_id,
sql_exec_id => v.max_sql_exec_id
) text_line
from (
select
sql_id,
max(sql_exec_id) max_sql_exec_id
from
v$sql_monitor
where
sql_id = '&m_sql_id'
and status like 'DONE%'
group by
sql_id
) v
;
spool off
set heading on
set linesize 132
set pagesize 60
And a sample of the text output, which is the result of monitoring the query “select * from dba_objects” (with an arraysize of 1,000 set in SQL*Plus):
SQL Monitoring Report SQL Text ------------------------------ select /*+ monitor */ * from dba_objects Global Information ------------------------------ Status : DONE (ALL ROWS) Instance ID : 1 Session : SYS (262:54671) SQL ID : 7nqa1nnbav642 SQL Execution ID : 16777216 Execution Started : 04/05/2018 19:43:42 First Refresh Time : 04/05/2018 19:43:42 Last Refresh Time : 04/05/2018 19:45:04 Duration : 82s Module/Action : sqlplus@linux12 (TNS V1-V3)/- Service : SYS$USERS Program : sqlplus@linux12 (TNS V1-V3) Fetch Calls : 93 Global Stats =========================================================================== | Elapsed | Cpu | IO | Other | Fetch | Buffer | Read | Read | | Time(s) | Time(s) | Waits(s) | Waits(s) | Calls | Gets | Reqs | Bytes | =========================================================================== | 0.31 | 0.29 | 0.00 | 0.02 | 93 | 6802 | 18 | 9MB | =========================================================================== SQL Plan Monitoring Details (Plan Hash Value=2733869014) ================================================================================================================================================================================= | Id | Operation | Name | Rows | Cost | Time | Start | Execs | Rows | Read | Read | Mem | Activity | Activity Detail | | | | | (Estim) | | Active(s) | Active | | (Actual) | Reqs | Bytes | (Max) | (%) | (# samples) | ================================================================================================================================================================================= | 0 | SELECT STATEMENT | | | | 83 | +0 | 1 | 91314 | | | | | | | 1 | VIEW | DBA_OBJECTS | 91084 | 2743 | 83 | +0 | 1 | 91314 | | | | | | | 2 | UNION-ALL | | | | 83 | +0 | 1 | 91314 | | | | | | | 3 | TABLE ACCESS BY INDEX ROWID | SUM$ | 1 | | | | | | | | | | | | 4 | INDEX UNIQUE SCAN | I_SUM$_1 | 1 | | | | | | | | | | | | 5 | TABLE ACCESS FULL | USER_EDITIONING$ | 1 | 2 | 1 | +0 | 872 | 1 | | | | | | | 6 | TABLE ACCESS BY INDEX ROWID BATCHED | OBJ$ | 1 | 3 | | | | | | | | | | | 7 | INDEX RANGE SCAN | I_OBJ1 | 1 | 2 | | | | | | | | | | | 8 | FILTER | | | | 83 | +0 | 1 | 91312 | | | | | | | 9 | HASH JOIN | | 91394 | 211 | 83 | +0 | 1 | 91312 | | | 2M | | | | 10 | TABLE ACCESS FULL | USER$ | 125 | 2 | 1 | +0 | 1 | 125 | | | | | | | 11 | HASH JOIN | | 91394 | 207 | 83 | +0 | 1 | 91312 | | | 1M | 100.00 | Cpu (1) | | 12 | INDEX FULL SCAN | I_USER2 | 125 | 1 | 1 | +0 | 1 | 125 | | | | | | | 13 | TABLE ACCESS FULL | OBJ$ | 91394 | 204 | 83 | +0 | 1 | 91312 | 13 | 9MB | | | | | 14 | TABLE ACCESS FULL | USER_EDITIONING$ | 1 | 2 | 1 | +0 | 872 | 1 | 2 | 16384 | | | | | 15 | NESTED LOOPS SEMI | | 1 | 2 | | | | | | | | | | | 16 | INDEX SKIP SCAN | I_USER2 | 1 | 1 | | | | | | | | | | | 17 | INDEX RANGE SCAN | I_OBJ4 | 1 | 1 | | | | | | | | | | | 18 | TABLE ACCESS FULL | USER_EDITIONING$ | 1 | 2 | | | | | | | | | | | 19 | HASH JOIN | | 2 | 4 | 1 | +82 | 1 | 1 | | | | | | | 20 | NESTED LOOPS | | 2 | 4 | 1 | +82 | 1 | 2 | | | | | | | 21 | STATISTICS COLLECTOR | | | | 1 | +82 | 1 | 2 | | | | | | | 22 | TABLE ACCESS FULL | LINK$ | 2 | 2 | 1 | +82 | 1 | 2 | 2 | 16384 | | | | | 23 | TABLE ACCESS CLUSTER | USER$ | 1 | 1 | 1 | +82 | 2 | 2 | | | | | | | 24 | INDEX UNIQUE SCAN | I_USER# | 1 | | 1 | +82 | 2 | 2 | 1 | 8192 | | | | | 25 | TABLE ACCESS FULL | USER$ | 1 | 1 | | | | | | | | | | ================================================================================================================================================================================= 1 row selected.
In a future note I’ll show an example of using one of these reports to identify the critical performance issue with an SQL statement that was raised recently on the ODC (OTN) database forum, but I’ll just point out one detail from this report. The “Time active (s)” says the query ran for about 83 seconds, but the Global Stats section tells us the elapsed time was 0.31 seconds. In this case the difference between these two is the time spent passing the data to the client.
Footnote
It is possible to force monitoring for an SQL statement with the /*+ monitor */ hint. Do be careful with this in production systems; each time the statement is executed the session will try to get the “Real-time descriptor latch” which is a latch with no latch children so if you monitor a lightweight statement that is called many times from many sessions you may find you lose a lot of time to latch contention and the attendant CPU spinning.
How-to generate random finance data
This time I demo how you can generate random financial data, to create test data for financial or commerce applications.
How-to generate random finance data
This time I demo how you can generate random financial data, to create test data for financial or commerce applications.
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