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FreeBSD basics – 8 – Running Linux Containers

Yann Neuhaus - Fri, 2024-12-20 00:22

When people talk about containers in FreeBSD, they usually talk about Jails. We’ve already seen how this works in general here and here. An additional option you have, is to install Podman on FreeBSD. Podman is well known in the Linux world and can be used to build and run containers. With the release of FreeBSD 14.2, the FreeBSD project is now also publishing OCI-compatible container images of FreeBSD.

We again start with a fresh installation of FreeBSD 14.2, nothing was added or modified. Podman, as with most of the additional software, can either be installed as a binary package or from the ports collection. If you want to install from the ports collection you can find Podman here:

root@freebsd14-latest:~ $ find /usr/ports/ -name "*podman*" 
/usr/ports/sysutils/podman
/usr/ports/sysutils/podman/files/podman_service.in
/usr/ports/sysutils/podman/files/podman.in
/usr/ports/sysutils/podman-suite

As it is faster to install from binary packages, we’ll do it like this for the scope of this post:

root@freebsd14-latest:~ $ pkg update
The package management tool is not yet installed on your system.
Do you want to fetch and install it now? [y/N]: y
Bootstrapping pkg from pkg+https://pkg.FreeBSD.org/FreeBSD:14:amd64/quarterly, please wait...
Verifying signature with trusted certificate pkg.freebsd.org.2013102301... done
Installing pkg-1.21.3...
Extracting pkg-1.21.3: 100%
Updating FreeBSD repository catalogue...
Fetching meta.conf: 100%    178 B   0.2kB/s    00:01    
Fetching data.pkg: 100%    7 MiB   7.5MB/s    00:01    
Processing entries: 100%
FreeBSD repository update completed. 35568 packages processed.
All repositories are up to date.
root@freebsd14-latest:~ $ pkg upgrade
Updating FreeBSD repository catalogue...
FreeBSD repository is up to date.
All repositories are up to date.
Updating database digests format: 100%
Checking for upgrades (1 candidates): 100%
Processing candidates (1 candidates): 100%
Checking integrity... done (0 conflicting)
Your packages are up to date.
root@freebsd14-latest:~ $ pkg install podman
Updating FreeBSD repository catalogue...
FreeBSD repository is up to date.
All repositories are up to date.
The following 33 package(s) will be affected (of 0 checked):

New packages to be INSTALLED:
        conmon: 2.1.12_3
        containernetworking-plugins: 0.5_9
        containers-common: 0.59.1
        gettext-runtime: 0.22.5
...
--
The FreeBSD port of the Podman container engine is experimental and should be
used for evaluation and testing purposes only.

$ sudo podman run --rm docker.io/dougrabson/hello

Podman can restart containers after a host is rebooted. To enable this, use:

$ sudo sysrc podman_enable=YES

and start the container with a restart policy:

$ sudo podman run -d --restart=always myimage

It is possible to run many Linux container images using FreeBSD's Linux emulation:

$ sudo sysrc linux_enable=YES
$ sudo service linux start
$ sudo podman run --rm --os=linux alpine cat /etc/os-release | head -1
NAME="Alpine Linux"

The package gives you quite some information at the end of the installation process. First of all, this is not yet considered production ready and should be used for testing only. Second, you will need to enable Podman and the Linux compatibility layer:

root@freebsd14-latest:~ $ sysrc podman_enable=YES
podman_enable:  -> YES
root@freebsd14-latest:~ $ sysrc linux_enable=YES
linux_enable: NO -> YES
root@freebsd14-latest:~ $ service linux start

If you want the containers to restart automatically, you should also mount the fdescfs file system:

root@freebsd14-latest:~ $ mount -t fdescfs fdesc /dev/fd
root@freebsd14-latest:~ $ df -h | grep fd
fdescfs               1.0K      0B    1.0K     0%    /compat/linux/dev/fd
fdescfs               1.0K      0B    1.0K     0%    /dev/fd

If you try to search for container images using Podman, you’ll notice that there is no result:

root@freebsd14-latest:~ $ podman search rockylinux

The reason is, that no container registries are defined, but this can easily be fixed by adding a registry to “/usr/local/etc/containers/registries.conf”:

root@freebsd14-latest:~ $ tail -1 /usr/local/etc/containers/registries.conf
unqualified-search-registries = ['docker.io']

Once this is configured, you can search the registry for container images:

root@freebsd14-latest:~ $ podman search rockylinux
NAME                                   DESCRIPTION
docker.io/rockylinux/rockylinux        
docker.io/library/rockylinux           The official build of Rocky Linux.
docker.io/rockylinux/rocky-toolbox     Toolbox image for Rocky Linux - https://gith...
docker.io/rockylinux/rockylinux-shim   RockyLinux shim-review images
docker.io/amd64/rockylinux             The official build of Rocky Linux.
docker.io/litmusimage/rockylinux       
docker.io/arm64v8/rockylinux           The official build of Rocky Linux.
docker.io/ericpaulsen/rockylinux       
docker.io/romcheck/rockylinux          
docker.io/robertdebock/rockylinux      Container to test Ansible roles in, includin...
docker.io/lightnear/rockylinux         
docker.io/accupara/rockylinux          
docker.io/detravi/rockylinux           
docker.io/ppc64le/rockylinux           The official build of Rocky Linux.
docker.io/aursu/rockylinux             
docker.io/s390x/rockylinux             The official build of Rocky Linux.
docker.io/uacontainers/rockylinux      Up-to-date Rocky Linux Docker images with th...
docker.io/buluma/rockylinux            
docker.io/gammabytehosting/rockylinux  Rocky Linux minimal image.
docker.io/whatwewant/rockylinux        
docker.io/kubestation/rockylinux       
docker.io/4geniac/rockylinux           
docker.io/jeksterslab/rockylinux       
docker.io/ihanick/rockylinux           
docker.io/douglarek/rockylinux

Running a container is exactly the same as you know it from Linux:

root@freebsd14-latest:~ $ podman run -it --rm --platform linux/amd64 rockylinux/rockylinux:9 /bin/bash
Resolving "rockylinux/rockylinux" using unqualified-search registries (/usr/local/etc/containers/registries.conf)
Trying to pull docker.io/rockylinux/rockylinux:9...
Getting image source signatures
Copying blob 3442e16c7069 done   | 
Copying config bb8a97547d done   | 
Writing manifest to image destination
WARN[0009] Failed to load cached network config: network podman not found in CNI cache, falling back to loading network podman from disk 
WARN[0009] Failed to load cached network config: network podman not found in CNI cache, falling back to loading network podman from disk 
Error: plugin type="bridge" failed (add): cni plugin bridge failed: The pf kernel module must be loaded to support ipMasq networks

… and this fails because we forgot to configure the container networking. There actually are instructions how to do this in the output of the Podman package installation:

Message from containernetworking-plugins-0.5_9:

--
Container networking relies on NAT to allow container network packets
out to the host's network. This requires a PF firewall to perform the
translation. A simple example is included - to use it:

# cp /usr/local/etc/containers/pf.conf.sample /etc/pf.conf
...
Edit /etc/pf.conf and set v4egress_if, v6egress_if to your network interface(s)
...
# sysrc pf_enable=YES
# service pf start

The sample PF configuration includes support for port redirections. These are
implemented as redirect rules in anchors nested under cni-rdr.

Support for redirecting connections from the container host to services running
inside a container is included for FreeBSD 13.3 and later. To enable this, first
load the pf kernel module, by adding pf_load="YES" to /boot/loader.conf and
enable PF support for these redirections using sysctl:

# kldload pf
# sysctl net.pf.filter_local=1
# service pf restart

Once this is done, all is fine:

root@freebsd14-latest:~ $ podman run -it --rm --platform linux/amd64 rockylinux/rockylinux:9 /bin/bash
[root@71ef409c1d40 /]$ cat /etc/os-release 
NAME="Rocky Linux"
VERSION="9.5 (Blue Onyx)"
ID="rocky"
ID_LIKE="rhel centos fedora"
VERSION_ID="9.5"
PLATFORM_ID="platform:el9"
PRETTY_NAME="Rocky Linux 9.5 (Blue Onyx)"
ANSI_COLOR="0;32"
LOGO="fedora-logo-icon"
CPE_NAME="cpe:/o:rocky:rocky:9::baseos"
HOME_URL="https://rockylinux.org/"
VENDOR_NAME="RESF"
VENDOR_URL="https://resf.org/"
BUG_REPORT_URL="https://bugs.rockylinux.org/"
SUPPORT_END="2032-05-31"
ROCKY_SUPPORT_PRODUCT="Rocky-Linux-9"
ROCKY_SUPPORT_PRODUCT_VERSION="9.5"
REDHAT_SUPPORT_PRODUCT="Rocky Linux"
REDHAT_SUPPORT_PRODUCT_VERSION="9.5"

Quite impressive and easy to setup. You might wonder if running Linux containers on FreeBSD actually is a thing. Personally, I think that this is really great, because it gives you another option in the FreeBSD world. Containers are everywhere today, and having more choice where to run them is great.

L’article FreeBSD basics – 8 – Running Linux Containers est apparu en premier sur dbi Blog.

Interval Search: Part 4. Dynamic Range Segmentation – interval quantization

XTended Oracle SQL - Thu, 2024-12-19 22:40

Forums, mailing lists, and StackOverflow are all great resources for Oracle performance discussions, but I’ve long thought it would be useful to have a dedicated online chat/group specifically for Oracle performance specialists. A place to share news, articles, and discuss performance issues. To test the waters, I’ve created a group: https://t.me/ora_perf. If you’re interested, feel free to join! Let’s build a central hub for Oracle performance discussions.

Before diving into the main topic, let me address a frequent question I’ve received regarding the earlier parts of this series:
You’re focusing on the rare case of date-only indexes (begin_date, end_date), but most real-world scenarios involve composite indexes with an ID field, like (id, begin_date, end_date).

Yes, it’s true that in practice, composite indexes with an ID field are more common. And exactly such scenarios was the reason of this series. However, I intentionally started with a simplified case to focus on the date filtering mechanics. All the issues, observations, conclusions, and solutions discussed so far are equally applicable to composite indexes.

For example, many production databases have identifiers that reference tens or even hundreds of thousands of intervals. The addition of an ID-based access predicate may reduce the scanned volume for a single query, but the underlying date range filtering issues remain. These inefficiencies often go unnoticed because people don’t realize their simple queries are doing tens of LIOs when they could be doing just 3-5, with response times reduced from 100 microseconds to 2 microseconds.

Even if your queries always use an equality predicate on the ID field, you’ll still encounter challenges with huge queries with joins, such as:

select *
from IDs
    join tab_with_history h
       on IDs.id = h.id
       and :dt between h.beg_date and h.end_date

Here, lookups for each ID against the composite index can become inefficient at scale compared to retrieving a pre-filtered slice for the target date.

To clarify, everything discussed in this series applies to composite indexes as well. The solutions can easily be extended to include ID fields by modifying just a few lines of code. Let’s now move to the main topic.

Dynamic Range Segmentation – Interval Quantization

In the earlier parts, you may have noticed a skew in my test data, with many intervals of 30 days generated for every hour. This naturally leads to the idea of reducing scan volume by splitting long intervals into smaller sub-intervals.

What is Interval Quantization?

Interval quantization is a known solution for this problem, but it often comes with drawbacks. Traditional quantization requires selecting a single fixed unit (e.g., 1 minute), which may not suit all scenarios. Using a small unit to cover all cases can lead to an explosion in the number of rows.

However, since Dynamic Range Segmentation (DRS) already handles short intervals efficiently, we can focus on quantizing only long intervals. For this example, we’ll:

  • Leave intervals of up to 1 hour as-is, partitioning them into two categories: up to 15 minutes and up to 1 hour.
  • Split longer intervals into sub-intervals of 1 day.
Creating a SQL Macro for Interval Splitting

To simplify the splitting of long intervals, we’ll write a SQL Macro:

create or replace function split_interval_by_days(beg_date date, end_date date)
  return varchar2 sql_macro
is
begin
  return q'{
     select/*+ no_decorrelate */
        case 
          when n = 1 
             then beg_date 
          else trunc(beg_date)+n-1
        end as sub_beg_date
       ,case
          when n<=trunc(end_date)-trunc(beg_date)
            then trunc(beg_date)+n -1/24/60/60
          else end_date
        end as sub_end_date
     from (select/*+ no_merge */ level n
           from dual
           connect by level<=trunc(end_date)-trunc(beg_date)+1
          )
  }';
end;
/

Source on github: https://github.com/xtender/xt_scripts/blob/master/blog/1.interval_search/drs.v2/split_interval_by_days.sql

This macro returns sub-intervals for any given range:

SQL> select * from split_interval_by_days(sysdate-3, sysdate);

SUB_BEG_DATE        SUB_END_DATE
------------------- -------------------
2024-12-17 02:30:34 2024-12-17 23:59:59
2024-12-18 00:00:00 2024-12-18 23:59:59
2024-12-19 00:00:00 2024-12-19 23:59:59
2024-12-20 00:00:00 2024-12-20 02:30:34
Updating the Domain Index 1. Partitioning Changes in ODCIIndexCreate_pr

We’ll modify the partitioning structure:

        partition by range(DURATION_MINUTES)
        (
            partition part_15_min   values less than (15)
           ,partition part_1_hour   values less than (60)
           ,partition part_1_day    values less than (1440)  --40*24*60
        )
2. Initial Data Population

We’ll use the SQL Macro to populate the index table with split intervals:

        -- Now populate the table.
        stmt2 := q'[INSERT INTO {index_tab_name} ( beg_date, end_date, rid )
            SELECT SUB_BEG_DATE as beg_date 
                  ,SUB_END_DATE as end_date 
                  ,P.rowid
            FROM "{owner}"."{tab_name}" P
            , split_interval_by_days(
                to_date(substr(P.{col_name}, 1,19),'YYYY-MM-DD HH24:MI:SS')
               ,to_date(substr(P.{col_name},21,19),'YYYY-MM-DD HH24:MI:SS')
               )
            ]';
3. Updating ODCIIndexInsert_pr 
  procedure ODCIIndexInsert_pr(
        ia       sys.ODCIIndexInfo,
        rid      VARCHAR2,
        newval   VARCHAR2,
        env      sys.ODCIEnv
    )
  IS
  BEGIN
        -- Insert into auxiliary table
        execute immediate 
           'INSERT INTO '|| get_index_tab_name(ia)||' (rid, beg_date, end_date)'
         ||'select 
             :rid, sub_beg_date, sub_end_date
            from split_interval_by_days(:beg_date, :end_date)'
           using rid,get_beg_date(newval),get_end_date(newval);
  END;
4. Query Generation in ODCIIndexStart_Pr

Update the SQL statement to account for the new partitions:

      stmt := q'{
        select rid from {tab_name} partition (part_15_min) p1
        where :cmpval between beg_date and end_date
          and end_date < :cmpval+interval'15'minute
        union all
        select rid from {tab_name} partition (part_1_hour) p2
        where :cmpval between beg_date and end_date
          and end_date < :cmpval+1/24
        union all
        select rid from {tab_name} partition (part_1_day ) p3
        where :cmpval between beg_date and end_date
          and end_date < :cmpval+1
        }';

Full code: https://github.com/xtender/xt_scripts/blob/master/blog/1.interval_search/drs.v2/2.idx_range_date_pkg.v2.pck

Results 
SQL> select count(*) from test_table where DATE_IN_RANGE(virt_date_range,date'2012-02-01')=1;

  COUNT(*)
----------
       943
SQL> @last

PLAN_TABLE_OUTPUT
-------------------------------------------------------------------------------------------------------
SQL_ID  17wncu9ftfzf6, child number 0
-------------------------------------
select count(*) from test_table where
DATE_IN_RANGE(virt_date_range,date'2012-02-01')=1

Plan hash value: 2131856123

-------------------------------------------------------------------------------------------------------
| Id  | Operation        | Name             | Starts | E-Rows | Cost  | A-Rows |   A-Time   | Buffers |
-------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT |                  |      1 |        |  9218 |      1 |00:00:00.01 |      15 |
|   1 |  SORT AGGREGATE  |                  |      1 |      1 |       |      1 |00:00:00.01 |      15 |
|*  2 |   DOMAIN INDEX   | TEST_RANGE_INDEX |      1 |        |       |    943 |00:00:00.01 |      15 |
-------------------------------------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------

   2 - access("XTENDER"."DATE_IN_RANGE"("VIRT_DATE_RANGE",TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd
              hh24:mi:ss'))=1)

So, by applying quantization with Dynamic Range Segmentation, we reduced the number of logical reads from 30 (in the simpler version) to 15—a 2x improvement.

Conclusion

In this example, we used partitions for 15 minutes, 1 hour, and 1 day for simplicity. In practice, optimal values will depend on the actual data. While the number of rows in the index increases, the fixed maximum interval length ensures consistently efficient results.

All series:

  1. Interval Search: Part 1. Optimizing Date Range Queries
  2. Interval Search: Part 2. Dynamic Range Segmentation – Simplified
  3. Interval Search: Part 3. Dynamic Range Segmentation – Custom Domain Index
  4. Interval Search: Part 4. Dynamic Range Segmentation – interval quantization
Categories: Development

Flood the Zone or Circle the Wagons: A Roadmap for Losing United States’ AI Leadership

Oracle Press Releases - Thu, 2024-12-19 14:46

Question about Merge and UDT

Tom Kyte - Thu, 2024-12-19 10:24
I'm using a UDT with dataset inside there as a table and i want to use that UDT on Merge statement. When using that UDT, i put that UDT inside "ON (" as following: "... ON (SELECT * FROM TABLE (UDT)) ..." then, how can i to use that UDT inside INSERT statment putting a only variable in the "VALUES" statment? For Example: MERGE INTO TABLE1 T1 USING (SELECT * FROM TABLE(UDT)) T2 ON (T1.X = T2.Y) WHEN NOT MATCHED THEN INSERT VALUES UDT; //<-------- here, i want only use UDT and that's all, how can i create something like this? The Table1 (T1) and UDT (T2) has the same structure
Categories: DBA Blogs

Fetch limited rows for update

Tom Kyte - Thu, 2024-12-19 10:24
Hi Tom, first at all, thanks for all your support. I wish a blessed christmas time for you, your team and families. I'm looking forward for the best practise of a cursor to fetch just one (or a few) row(s) on my own sorting and lock them. Without locking the whole resultset or include all rows with the condition. <code> select * from MyTable where < MyCondition > order By < MyOrderby > fetch first 1 row only for update skip locked; </code> Unfortunately the combination of fetch-first-only and for update causes a ORA-02014 :( - without fetch-first-only it will lock the whole resultset - a rownum condition instead of fetch-first-only will not consider my orderby - an inner subselect with fetch-first-only will not skip the locked rows and finally fetch zero rows if the inner sql only fetch already locked rows <code> select * from MyTable where Rowid in (select Rowid from MyTable where < MyCondition > order By < MyOrderby > fetch first 1 row only) for update skip locked; </code> Whats your best practice or advice? Thanks, Norman
Categories: DBA Blogs

Recovery with SQL*PLUS in embedded korn shell script

Tom Kyte - Thu, 2024-12-19 10:24
We have a production DB that is used for reporting is been attempted to clone with NetApp Snapmirror technology. The current clone is done with old method placing the tablespaces of PROD DB in backup mode and then copying the files using OS ?cp? tool to the designated clone DB directories and run the necessary DB layer clone steps. This works fine but now taking extra long time to complete and impacting business functions. With NetApp SNapmirror technology all steps are working up to the DB layer clone steps. There is an issue with very last steps of recovering the DB after SnapMirror has performed. The step used is ?alter database recover automatic using backup controlfile until cancel? as that seems to be the only option available according Oracle Doc ID: DATAFILE NEEDS MORE RECOVERY TO BE CONSISTENT ORA-1194 ORA-1547 ORA-1110 (Doc ID 1528788.1) - Scenario 2: Backup Controlfile is Used for recovery. Doing this recovery interactively via SQL*PLUS needs placing the redo log file path when prompted. Then DB recover successfully. See below for output. SQL> RECOVER DATABASE USING BACKUP CONTROLFILE UNTIL CANCEL ; ORA-00279: change 75786588505 generated at 12/06/2024 13:41:35 needed for thread 1 ORA-00289: suggestion : /arch_poct/archive/OFPOC/arch_1186748276_1_18.arc ORA-00280: change 75786588505 for thread 1 is in sequence #18 Specify log: {<RET>=suggested | filename | AUTO | CANCEL} '/redo_poct/oradata/OFPOC/redo06.log' Log applied. Media recovery complete. SQL> alter database open resetlogs ; Database altered. But this clone process has to be done on daily basis and must be automated. When scripted there is no way with SQL*PLUS to be read from a file containing `/redo_poct/oradata/OFPOC/redo06.log' for it?s standard input. Below is the script #! /usr/bin/ksh sqlplus "/ as sysdba" < /projects/of/poc/spt/log/setup_sql_redo_20241217.log <<EOF set echo on alter database recover automatic using backup controlfile until cancel; EOF Where cat /projects/of/poc/spt/log/setup_sql_redo_20241217.log '/redo_poct/oradata/OFPOC/redo06.log' Output ? /projects/gen/ksh/working> ./TestRecovery.sh SQL*Plus: Release 11.2.0.2.0 Production on Tue Dec 17 17:29:00 2024 Copyright (c) 1982, 2010, Oracle. All rights reserved. Connected to: Oracle Database 11g Enterprise Edition Release 11.2.0.2.0 - 64bit Production With the Partitioning, OLAP, Data Mining and Real Application Testing options SQL> SQL> alter database recover automatic using backup controlfile until cancel * ERROR at line 1: ORA-00279: change 75787505640 generated at 12/16/2024 11:21:36 needed for thread 1 ORA-00289: suggestion : /arch_poct/archive/OFPOC/arch_1186748276_1_157.arc ORA-00280: change 75787505640 for thread 1 is in sequence #157 ORA-00278: log file '/arch_poct/archive/OFPOC/arch_1186748276_1_157.arc' no longer needed for this recovery ORA-00308: cannot open archived log '/arch_poct/archive/OFPOC/arch_1186748276_1_15...
Categories: DBA Blogs

Oracle_Loader External Table using Fixed Width

Tom Kyte - Thu, 2024-12-19 10:24
I'm using external tables everyday to load csv files but I'm having great difficulty loading my first FIXED WIDTH file. I've tried several different access parameter variations and the CREATE TABLE command compiles without error but when I select the table, I get the following error. In my several iterations, I may get a different "KUP-01005: syntax error" but I can't seem to get past this: Error Message: <code>select * from rzedelq;</code> ORA-29913: error in executing ODCIEXTTABLEOPEN callout ORA-29400: data cartridge error KUP-00554: error encountered while parsing access parameters KUP-01005: syntax error: found "badfile": expecting one of: "all, column, convert_error, csv, date_format, enclosed, ignore_chars_after_eor, (, ltrim, lrtrim, ldrtrim, missing, notrim, nullif, number_format, numeric_characters, optionally, rtrim, remove_quotes, reject, terminated, truncate_columns" KUP-01007: at line 2 column 13 29913. 00000 - "error in executing %s callout" *Cause: The execution of the specified callout caused an error. *Action: Examine the error messages take appropriate action. -- <code> CREATE TABLE rzedelq ( rzedelq_type VARCHAR2(1), rzedelq_dob DATE, rzedelq_last_name VARCHAR2(30), rzedelq_first_name VARCHAR2(30), rzedelq_balance NUMBER(6) ) ORGANIZATION EXTERNAL ( TYPE ORACLE_LOADER DEFAULT DIRECTORY ext_data ACCESS PARAMETERS ( RECORDS FIXED 76 FIELDS BADFILE 'rzedelq.bad' LOGFILE 'rzedelq.log' MISSING FIELD VALUES ARE NULL ( rzedelq_record_type (01:01) CHAR(1), rzedelq_dob (02:09) CHAR(8) DATE 'yyyymmdd' NULLIF rzedelq_dob='00000000', rzedelq_last_name (10:39) CHAR(30), rzedelq_first_name (40:69) CHAR(30), rzedelq_balance (70:75) NUMBER(6) ) ) LOCATION ('rzedelq.dat') ) REJECT LIMIT UNLIMITED ; </code> Sample data file: <code> --'rzedelq.dat'-- 119811218ANDERSEN AIMEE 366910 219121006COWGER AMANDA 030900 119030707GESLIN ANDREA 150910 319041125HATFIELD CARRIE 055900 119150913MERRELL CONNIE 018920 419761024MESSINGER JASON 010960 119170708PRIMROSE JOHN 030920 519980721REEVES KAILYNN 018930 119690511SAFARIK ROBERT 021980 </code> -- Any Ideas? Any help?
Categories: DBA Blogs

Check if a pasword parameter is passed to an sql script and process based on that

Tom Kyte - Thu, 2024-12-19 10:24
I am trying to create an sql script that creates a user and if a password is supplied as a parameter to use it and if no parameter is passed have the sql prompt for the password. This is what i tried but I am obviously a bit off since it asks for the Value of &1 immediately if it is not passed. If I do pass it a password it gives errors and then prompts for Password and creates user using that password. Create_TEST_User.sql <code>define Password = '&1' SET VERIFY OFF; if &Password is NULL THEN ACCEPT Password PROMPT 'Enter value for Password: ' HIDE end if; CREATE USER "TEST" IDENTIFIED BY "&Password" DEFAULT TABLESPACE "USERS" TEMPORARY TABLESPACE "TEMP"; GRANT "CONNECT" TO "TEST"; </code> @Create_TEST_User.sql testpassword-1234 Error starting at line : 3 File @ /opt/oracle/sql/Create_TEST_User.sql In command - if &Password is NULL Error report - Unknown Command Error starting at line : 4 File @ /opt/oracle/sql/Create_TEST_User.sql In command - THEN Error report - Unknown Command Enter value for Password: ******** Error starting at line : 6 File @ /opt/oracle/sql/Create_TEST_User.sql In command - end if Error report - Unknown Command User "TEST" created.
Categories: DBA Blogs

What Should you do if your Oracle Database is Hacked?

Pete Finnigan - Thu, 2024-12-19 10:24
This is the second talk that I did at the recent UKOUG conference at the East Side rooms in Birmingham. This talk discusses how you should respond if you think that your database has been breached or if you unfortunately....[Read More]

Posted by Pete On 19/12/24 At 02:26 PM

Categories: Security Blogs

Accessing values stored in a global context from APEX

Flavio Casetta - Thu, 2024-12-19 09:13
Have you ever tried to retrieve a value using SYS_CONTEXT from a user-defined context accessed globally?
Chances are that you will only retrieve NULLs.

After some testing, following a series of inexplicable results, a bell rang in my head pointing to something dealing with a few required values that a procedure launched from an APEX application needed in order to process the data.

It turns out that APEX is setting the CLIENT_IDENTIFIER value in USERENV, that is the value that you can retrieve using function SYS_CONTEXT('USERENV', 'CLIENT_IDENTIFIER').
If you have a context defined as ACCESSED GLOBALLY, there are some rules explained in the documentation about what you could get given certain conditions (link for Oracle 19c).

At the end of the discussion, the documentation says that if you are getting NULLs, then you might have a problem with the CLIENT_IDENTIFIER and you need to clear it using:
DBMS_SESSION.CLEAR_IDENTIFIER;

It turned out that after clearing the CLIENT_IDENTIFIER, the missing values started finally to appear because, indeed, APEX is setting the CLIENT_IDENTIFIER with a value composed like this:
<APP_USER>:<APP_SESSION>.

Now, in my case it was sound and safe to clear the CLIENT_IDENTIFIER because my process was running in background and the associated Oracle session is closed when the job terminates, but if you need to retrieve these values as part of an interactive process run inside an APEX page, I'd say that you would be better off creating a wrapper function for SYS_CONTEXT where you :

  1. save the current CLIENT_IDENTIFIER in a variable
  2. clear it using DBMS_SESSION.CLEAR_IDENTIFIER
  3. assign the desired value retrieved from the global context to another variable
  4. restore the original CLIENT_IDENTIFIER using DBMS_SESSION.SET_IDENTIFIER
  5. return the desired value.
I didn't test this suggestion yet as I am busy with other urgent stuff, so caveat emptor!
Categories: DBA Blogs

Oracle Database Replay for a RAC environment

Yann Neuhaus - Thu, 2024-12-19 04:18

The database Capture/Replay feature of the Real Application Testing (RAT) suite enables you to capture the workload from a production database and replay it on a test or development environment. This allows for realistic testing of database changes, such as upgrades, patches, or hardware migrations.

In this blog, we’ll explore how to accomplish this when both your production and test databases are configured in a two-node RAC environment.

Restrictions :

You should be aware that some workload operations are not supported, such as flashback queries and distributed transactions.

In most cases, Database Replay refrains from capturing these operations, or does not replay them. However you should refer to the oracle documentation bellow for the full list of non-supported operations and related considerations :

Oracle Database Documentation

The Workload Capture

The capture procedure on a RAC database is the same as for a single instance database, you just need to run it on one of the instances, without adding an instance filter :

The path you use to store the raw workload files must be defined as a database directory, and must be empty.

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SQL> CREATE DIRECTORY capture_dir AS '/u90/db_capture/';

It is recommended, but NOT mandatory, to restart your database before the capture, so that all current processes are finished, and the capture would catch absolutely all the changes from the timestamp of its start.

Let’s take for instance a 4 hours workload capture (14400 seconds) :

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BEGIN
  DBMS_WORKLOAD_CAPTURE.start_capture (name     => 'capture_4h',
                                       dir      => 'CAPTURE_DIR',
                                       duration => 14400);
END;
/

This package will capture the workload on both RAC instances for 4 hours and will automatically stop. If you need to stop it earlier, you can do it manually using:

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SQL>  exec DBMS_WORKLOAD_CAPTURE.finish_capture;

The capture process does not significantly impact performance (it adds about 3-5% CPU overhead). However, it may require substantial storage space. A common reason to stop the capture prematurely is running out of space in the designated directory.

Oracle Support Note Doc ID 1920275.1 provides a method to estimate the space required. For a detailed explanation, please refer to the note:

Doc ID 1920275.1

The general formula for the space needed provided by this note is:

 
2 * Bytes received via SQL*Net from client (as seen in AWR or StatsPack).

Alternatively, you can perform a short capture, such as for 10 minutes, and extrapolate the estimate based on the size captured during that period.

At the end of the capture, you should generate an html summary, and export related AWR data, for that, you’ll need the ID of you capture :

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SELECT id, name FROM dba_workload_captures;
SQL>
        ID NAME
---------- ------------------------------
        11 capture_4h
         2 test_capture_1
 
SQL>

So the capture id in my case is : 11

– Generating The html report (It is generated in the directory of the capture) :

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SQL> DECLARE
  l_report  CLOB;
BEGIN
  l_report := DBMS_WORKLOAD_CAPTURE.report(capture_id => 11,
                                           format     => DBMS_WORKLOAD_CAPTURE.TYPE_HTML);
END;

– Exporting the AWR data (It generates a datapump dump file contaiting all awr data of the period of the capture) :

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SQL> exec DBMS_WORKLOAD_CAPTURE.export_awr (capture_id => 11);
The Replay

To prepare the replay you need two things :

– To copy all the files from the directory of the capture to the test system (As it is two nodes RAC it should be on a shared location).

– Prepare a test database : The html report of the capture contains the SCN of the start, it’s best practice for instance to duplicate your database up to that specific SCN, in the test environment, before applying the changes you want to evaluate (for instance an upgrade, or parameters changes).

Once your test database is ready, and the captured files are available on a shared location :

– We create the directory of the replay :

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SQL> CREATE OR REPLACE DIRECTORY replay_dir AS '/u90/replay/';

The captured raw files must be processed by the database, before the capture could be replayed, this step could take some time depending of the size of the workload raw files :

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SQL> exec DBMS_WORKLOAD_REPLAY.process_capture('REPLAY_DIR');

Then we initiate the replay (just an initiation, the replay is not yet started) :

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SQL> exec DBMS_WORKLOAD_REPLAY.initialize_replay(replay_name => 'replay_capture_4h', replay_dir  => 'REPLAY_DIR');

This step generated an entry in the DBA_WORKLOAD_REPLAYS view, we must retrieve the associated id :

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SQL> select id,status from dba_workload_replays;
 
        ID STATUS
---------- ----------------------------------------
         1 COMPLETED
        11 COMPLETED
        21 INITIALIZED

So, here, the ID of the replay is 21.

Next step is to remap the workload connections. To be able to apply the replay on both instances, we must use a TNS entry to a scan host and scan service :

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SQL>
set linesize 250
set pages 9999
spool remap_connections.sql
select 'exec dbms_workload_replay.remap_connection ( connection_id => '||conn_id||', replay_connection => ''(DESCRIPTION=(ADDRESS=(PROTOCOL=TCP)(HOST=a_scan_host)(PORT=your_port))(CONNECT_DATA=(SERVICE_NAME=a_scan_service)))'');' from dba_workload_connection_map where replay_id=21;
spool off

Then we clean and execute the script :

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sqlplus / as sysdba
SQL>
@remap_connections.sql
…………………
PL/SQL procedure successfully completed.
 
 
PL/SQL procedure successfully completed.
 
SQL>

Next we prepare the replay :

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SQL> exec DBMS_WORKLOAD_REPLAY.prepare_replay (synchronization => TRUE);
 
PL/SQL procedure successfully completed.
 
SQL>

synchronization => TRUE : ensures that the replay sessions are synchronized, maintaining the order and dependency between transactions as they occurred during the workload capture.

Checking the status of the replay :

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SQL> select id,status from dba_workload_replays;
 
        ID STATUS
---------- ----------------------------------------
         1 COMPLETED
        11 COMPLETED
        21 PREPARE

Next we need to calibrate the replay clients, we use the wrc program in calibrate mode. wrc is The Workload Replay Client tool, used to replay database workload captured by Oracle Database.

The calibration mode purpose is to ensures that the workload replay environment has enough replay clients to handle the workload in the capture. After calibration, the wrc tool will output the minimum number of replay clients required.

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[oracle@LinuxHost~]$ wrc mode=calibrate replaydir=/u90/replay
 
Workload Replay Client: Release 19.23.0.0.0 - Production on Wed Dec 11 10:58:06 2024
 
Copyright (c) 1982, 2019, Oracle and/or its affiliates.  All rights reserved.
 
 
 
Workload Report
-----------------------
Recommendation:
Consider using at least 52 clients divided among 14 CPU(s)
You will need at least 152 MB of memory per client process.
If your machine(s) cannot match that number, consider using more clients.
 
Workload Characteristics:
- max concurrency: 3984 sessions
- total number of sessions: 56136
 
Assumptions:
- 100 concurrent sessions per client process
- 4 client processes per CPU
- 256 KB of memory cache per concurrent session
- think time scale = 100
- connect time scale = 100
- synchronization = TRUE
 
[oracle@LinuxHost ~]$

Based on this calibration, and after checking the cpu and memory available, I will use 56 clients (56 x 152 MB = 8.5G of minimal memory needed for the clients : Ok for me).

And this means using 28 clients per node, as I want to balance the overhead on the two nodes.

The command to start a single client is :

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[oracle@LinuxHost]$ wrc system/password@test mode=replay replaydir=/u90/replay

But I prepared a script to start 28 clients at once in background mode, for instance in the first node :

 
[oracle@LinuxHost]$ cat replay_node1.sh
#!/bin/bash
 
export ORACLE_HOME=/u01/app/oracle/product/19.0.0.0/dbhome_1
export PATH=/home/oracle/.local/bin:/home/oracle/bin:/usr/local/bin:/usr/bin:/usr/local/sbin:/usr/sbin:/u01/app/oracle/product/19.0.0.0/dbhome_1/bin
 
# Configuration
USER="system"
PASSWORD="Oracle$"
DB_CONNECT="Instance1"
MODE="replay"
REPLAY_DIR="/u90/replay"
LOG_DIR="./wrc_logs"  # Directory to store log files
NUM_CLIENTS=28        # Number of clients to start
 
# Ensure the log directory exists
mkdir -p $LOG_DIR

# Start WRC clients in a loop
for ((i=1; i<=NUM_CLIENTS; i++))
do
nohup wrc ${USER}/${PASSWORD}@${DB_CONNECT} mode=${MODE} replaydir=${REPLAY_DIR} > ${LOG_DIR}/wrc_client_$i.log 2>&1 &
echo "Started WRC client $i, log: ${LOG_DIR}/wrc_client_$i.log"
done
 
echo "All $NUM_CLIENTS clients started. Logs are in $LOG_DIR."
 
[oracle@LinuxHost]

starting the clients on the first node :

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[oracle@LinuxHost]$ ./replay_node1.sh
Started WRC client 1, log: ./wrc_logs/wrc_client_1.log
Started WRC client 2, log: ./wrc_logs/wrc_client_2.log
Started WRC client 3, log: ./wrc_logs/wrc_client_3.log
Started WRC client 4, log: ./wrc_logs/wrc_client_4.log
Started WRC client 5, log: ./wrc_logs/wrc_client_5.log
Started WRC client 6, log: ./wrc_logs/wrc_client_6.log
Started WRC client 7, log: ./wrc_logs/wrc_client_7.log
Started WRC client 8, log: ./wrc_logs/wrc_client_8.log
Started WRC client 9, log: ./wrc_logs/wrc_client_9.log
Started WRC client 10, log: ./wrc_logs/wrc_client_10.log
Started WRC client 11, log: ./wrc_logs/wrc_client_11.log
Started WRC client 12, log: ./wrc_logs/wrc_client_12.log
Started WRC client 13, log: ./wrc_logs/wrc_client_13.log
Started WRC client 14, log: ./wrc_logs/wrc_client_14.log
Started WRC client 15, log: ./wrc_logs/wrc_client_15.log
Started WRC client 16, log: ./wrc_logs/wrc_client_16.log
Started WRC client 17, log: ./wrc_logs/wrc_client_17.log
Started WRC client 18, log: ./wrc_logs/wrc_client_18.log
Started WRC client 19, log: ./wrc_logs/wrc_client_19.log
Started WRC client 20, log: ./wrc_logs/wrc_client_20.log
Started WRC client 21, log: ./wrc_logs/wrc_client_21.log
Started WRC client 22, log: ./wrc_logs/wrc_client_22.log
Started WRC client 23, log: ./wrc_logs/wrc_client_23.log
Started WRC client 24, log: ./wrc_logs/wrc_client_24.log
Started WRC client 25, log: ./wrc_logs/wrc_client_25.log
Started WRC client 26, log: ./wrc_logs/wrc_client_26.log
Started WRC client 27, log: ./wrc_logs/wrc_client_27.log
Started WRC client 28, log: ./wrc_logs/wrc_client_28.log
All 28 clients started. Logs are in ./wrc_logs.
[oracle@LinuxHost]$

We do the same thing on the second node, we just need to change the DB_CONNECT variable in the script.

Finally, we can start the replay :

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BEGIN
  DBMS_WORKLOAD_REPLAY.start_replay;
END;
/

The replay is finally started, it can be monitored by :

– Querying the views : dba_workload_replays and v$workload_replay_thread.
– Checking the clients log files.

Hope it helps !

L’article Oracle Database Replay for a RAC environment est apparu en premier sur dbi Blog.

Interval Search Series: Simplified, Advanced, and Custom Solutions

XTended Oracle SQL - Wed, 2024-12-18 23:47
  1. Interval Search: Part 1. Optimizing Date Range Queries
  2. Interval Search: Part 2. Dynamic Range Segmentation – Simplified
  3. Interval Search: Part 3. Dynamic Range Segmentation – Custom Domain Index
  4. Interval Search: Part 4. Dynamic Range Segmentation – interval quantization
Categories: Development

Interval Search: Part 3. Dynamic Range Segmentation – Custom Domain Index

XTended Oracle SQL - Wed, 2024-12-18 23:40

In this part, I’ll show how to implement Dynamic Range Segmentation (DRS) explained in the previous part using a custom Domain Index, allowing you to apply this optimization with minimal changes to your existing tables.

1. Creating the Function and Operator

First, we create a function that will be used to define the operator for the domain index:

CREATE OR REPLACE FUNCTION F_DATE_IN_RANGE(date_range varchar2, cmpval date)
RETURN NUMBER deterministic
AS
BEGIN
  -- simple concatenation: beg_date;end_date
  -- in format YYYY-MM-DD HH24:MI:SS
  if cmpval between to_date(substr(date_range, 1,19),'YYYY-MM-DD HH24:MI:SS')
                and to_date(substr(date_range,21,19),'YYYY-MM-DD HH24:MI:SS')
  then
    return 1;
  else
    return 0;
  end if;
END;
/

Next, we create the operator to use this function:

CREATE OPERATOR DATE_IN_RANGE BINDING(VARCHAR2, DATE)
  RETURN NUMBER USING F_DATE_IN_RANGE;
/
2. Creating the idx_range_date_pkg Package

We define a package (idx_range_date_pkg) that contains the necessary procedures to manage the domain index. The full implementation is too lengthy to include here but is available on GitHub.

3. Creating the idx_range_date_type

The type idx_range_date_type implements the ODCI extensible indexing interface, which handles operations for the domain index.
The code is available on GitHub.

Key Features of idx_range_date_type

Internal Data Segmentation:
The type and package create and maintain an internal table of segmented data. For example, the procedure ODCIIndexCreate_pr creates a partitioned table:

        stmt1 := 'CREATE TABLE ' || get_index_tab_name(ia)
        ||q'[
        (
           beg_date date
          ,end_date date
          ,rid rowid
          ,DURATION_MINUTES number as ((end_date-beg_date)*24*60)
        )
        partition by range(DURATION_MINUTES)
        (
            partition part_15_min   values less than (15)
           ,partition part_2_days   values less than (2880)   --2*24*60
           ,partition part_40_days  values less than (57600)  --40*24*60
           ,partition part_400_days values less than (576000) --400*24*60
           ,partition p_max         values less than (maxvalue)
        )
        ]';

Efficient Query Execution:
The procedure ODCIIndexStart_pr executes range queries against this internal table:

      -- This statement returns the qualifying rows for the TRUE case.
      stmt := q'{
        select rid from {tab_name} partition (part_15_min) p1
        where :cmpval between beg_date and end_date
          and end_date<=:cmpval+interval'15'minute
        union all
        select rid from {tab_name} partition (part_2_days) p1
        where :cmpval between beg_date and end_date
          and end_date<=:cmpval+2
        union all
        select rid from {tab_name} partition (part_40_days) p1
        where :cmpval between beg_date and end_date
          and end_date<=:cmpval+40
        union all
        select rid from {tab_name} partition (part_400_days) p1
        where :cmpval between beg_date and end_date
          and end_date<=:cmpval+400
        union all
        select rid from {tab_name} partition (p_max) p1
        where :cmpval between beg_date and end_date
        }';

Returning Results:
The ODCIIndexFetch_pr procedure retrieves the list of qualifying ROWID values:

    FETCH cur BULK COLLECT INTO rowids limit nrows;

Here is the corresponding function implementation:

    MEMBER FUNCTION ODCIIndexFetch(
        self in out idx_range_date_type,
        nrows NUMBER,
        rids  OUT sys.ODCIRidList,
        env   sys.ODCIEnv
    ) RETURN NUMBER 
    IS
      cnum number;
      cur sys_refcursor;
    BEGIN
      idx_range_date_pkg.p_debug('Fetch: nrows='||nrows);
      cnum:=self.curnum;
      cur:=dbms_sql.to_refcursor(cnum);
      idx_range_date_pkg.p_debug('Fetch: converted to refcursor');

      idx_range_date_pkg.ODCIIndexFetch_pr(nrows,rids,env,cur);
      
      self.curnum:=dbms_sql.to_cursor_number(cur);
      RETURN ODCICONST.SUCCESS;
    END;
4. Creating the INDEXTYPE 
CREATE OR REPLACE INDEXTYPE idx_range_date_idxtype
FOR
  DATE_IN_RANGE(VARCHAR2,DATE)
USING idx_range_date_type;
/

Now we created all the required objects, so it’s time to create the index.

5. Adding a Virtual Generated Column

Since the ODCI interface only supports indexing a single column, we combine beg_date and end_date into a virtual generated column:

alter table test_table 
  add virt_date_range varchar2(39)
      generated always as
       (to_char(beg_date,'YYYY-MM-DD HH24:MI:SS')||';'||to_char(end_date,'YYYY-MM-DD HH24:MI:SS'))
/
6. Creating the Index

We create the domain index on the virtual column:

CREATE INDEX test_range_index ON test_table (virt_date_range)
  INDEXTYPE IS idx_range_date_idxtype
/
7. Testing the Index

Let’s test the index with a query:

SQL> select count(*) from test_table where DATE_IN_RANGE(virt_date_range,date'2012-02-01')=1;

  COUNT(*)
----------
       943

Execution Plan:

SQL> @last

PLAN_TABLE_OUTPUT
---------------------------------------------------------------------------------------------------------------
SQL_ID  17wncu9ftfzf6, child number 0
-------------------------------------
select count(*) from test_table where
DATE_IN_RANGE(virt_date_range,date'2012-02-01')=1

Plan hash value: 2131856123

---------------------------------------------------------------------------------------------------------------
| Id  | Operation        | Name             | Starts | E-Rows |E-Bytes| Cost  | A-Rows |   A-Time   | Buffers |
---------------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT |                  |      1 |        |       |  9218 |      1 |00:00:00.01 |      30 |
|   1 |  SORT AGGREGATE  |                  |      1 |      1 |    40 |       |      1 |00:00:00.01 |      30 |
|*  2 |   DOMAIN INDEX   | TEST_RANGE_INDEX |      1 |        |       |       |    943 |00:00:00.01 |      30 |
---------------------------------------------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------

   2 - access("XTENDER"."DATE_IN_RANGE"("VIRT_DATE_RANGE",TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd
              hh24:mi:ss'))=1)

Results: Only 30 logical reads were needed for the same date 2012-02-01!

Summary

Using a custom domain index allows us to implement this method with minimal changes to existing tables. This method efficiently handles interval queries while requiring significantly fewer logical reads.

In the next part, I will demonstrate how to enhance the Dynamic Range Segmentation method by introducing interval quantization—splitting longer intervals into smaller sub-intervals represented as separate rows.

Categories: Development

Interval Search: Part 2. Dynamic Range Segmentation – Simplified

XTended Oracle SQL - Wed, 2024-12-18 22:31

In the previous part, I discussed the most efficient known methods for optimizing range queries. In this part, I’ll introduce a simple version of my custom approach, which I call Dynamic Range Segmentation (DRS).

As explained earlier, a significant issue with conventional approaches is the lack of both boundaries in the ACCESS predicates. This forces the database to scan all index entries either above or below the target value, depending on the order of the indexed columns.

Dynamic Range Segmentation solves this problem by segmenting data based on the interval length.

Let’s create a table partitioned by interval lengths with the following partitions:

  • part_15_min: Intervals shorter than 15 minutes.
  • part_2_days: Intervals between 15 minutes and 2 days.
  • part_40_days: Intervals between 2 days and 40 days.
  • part_400_days: Intervals between 40 days and 400 days.
  • p_max: All remaining intervals

Here’s the DDL for the partitioned table:

create table Dynamic_Range_Segmentation(
   beg_date date
  ,end_date date
  ,rid rowid
  ,DURATION_MINUTES number as ((end_date-beg_date)*24*60)
)
partition by range(DURATION_MINUTES)
(
    partition part_15_min   values less than (15)
   ,partition part_2_days   values less than (2880)   --2*24*60
   ,partition part_40_days  values less than (57600)  --40*24*60
   ,partition part_400_days values less than (576000) --400*24*60
   ,partition p_max         values less than (maxvalue)
);

The DURATION_MINUTES column is a virtual generated column that computes the interval length in minutes as the difference between beg_date and end_date.

We will explore the nuances of selecting specific partition boundaries in future parts. For now, let’s focus on the approach itself.

We populate the partitioned table with the same test data and create a local index on (end_date, beg_date):

insert/*+append parallel(4) */ into Dynamic_Range_Segmentation(beg_date,end_date,rid)
select beg_date,end_date,rowid from test_table;

create index ix_drs on Dynamic_Range_Segmentation(end_date,beg_date) local;
call dbms_stats.gather_table_stats('','Dynamic_Range_Segmentation');
Optimizing the Query

By segmenting the data, we can assert with certainty that if we are searching for records in the part_15_min partition, the qualifying records must satisfy the condition
end_date <= :dt + INTERVAL '15' MINUTE
because no intervals in this partition exceed 15 minutes in length. This additional boundary provides the much-needed second predicate.

Thus, we can optimize our query by addressing each partition individually, adding upper boundaries for all partitions except the last one (p_max):

select count(*),min(beg_date),max(end_date) from (
  select * from Dynamic_Range_Segmentation partition (part_15_min) p1
  where date'2012-02-01' between beg_date and end_date
    and end_date<=date'2012-02-01'+interval'15'minute
  union all
  select * from Dynamic_Range_Segmentation partition (part_2_days) p1
  where date'2012-02-01' between beg_date and end_date
    and end_date<=date'2012-02-01'+2
  union all
  select * from Dynamic_Range_Segmentation partition (part_40_days) p1
  where date'2012-02-01' between beg_date and end_date
    and end_date<=date'2012-02-01'+40  union all
  select * from Dynamic_Range_Segmentation partition (part_400_days) p1
  where date'2012-02-01' between beg_date and end_date
    and end_date<=date'2012-02-01'+400
  union all
  select * from Dynamic_Range_Segmentation partition (p_max) p1
  where date'2012-02-01' between beg_date and end_date
);

Results:

  COUNT(*) MIN(BEG_DATE)       MAX(END_DATE)
---------- ------------------- -------------------
       943 2011-01-03 00:00:00 2013-03-03 00:00:00

SQL> select * from table(dbms_xplan.display_cursor('','','all allstats last -alias -projection'));

PLAN_TABLE_OUTPUT
----------------------------------------------------------------------------------------------------------------------------------------------
SQL_ID  204zu1xhdqcq3, child number 0
-------------------------------------
select count(*),min(beg_date),max(end_date) from (   select * from
Dynamic_Range_Segmentation partition (part_15_min) p1   where
date'2012-02-01' between beg_date and end_date     and
end_date<=date'2012-02-01'+interval'15'minute   union all   select *
from Dynamic_Range_Segmentation partition (part_2_days) p1   where
date'2012-02-01' between beg_date and end_date     and
end_date<=date'2012-02-01'+2   union all   select * from
Dynamic_Range_Segmentation partition (part_40_days) p1   where
date'2012-02-01' between beg_date and end_date     and
end_date<=date'2012-02-01'+40  union all   select * from
Dynamic_Range_Segmentation partition (part_400_days) p1   where
date'2012-02-01' between beg_date and end_date     and
end_date<=date'2012-02-01'+400   union all   select * from
Dynamic_Range_Segmentation partition (p_max) p1   where
date'2012-02-01' between beg_date and end_date )

Plan hash value: 1181465968

----------------------------------------------------------------------------------------------------------------------------------------------
| Id  | Operation                 | Name   | Starts | E-Rows |E-Bytes| Cost (%CPU)| E-Time   | Pstart| Pstop | A-Rows |   A-Time   | Buffers |
----------------------------------------------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT          |        |      1 |        |       |    24 (100)|          |       |       |      1 |00:00:00.01 |      28 |
|   1 |  SORT AGGREGATE           |        |      1 |      1 |    18 |            |          |       |       |      1 |00:00:00.01 |      28 |
|   2 |   VIEW                    |        |      1 |   1582 | 28476 |    24   (0)| 00:00:01 |       |       |    943 |00:00:00.01 |      28 |
|   3 |    UNION-ALL              |        |      1 |        |       |            |          |       |       |    943 |00:00:00.01 |      28 |
|   4 |     PARTITION RANGE SINGLE|        |      1 |      4 |    64 |     3   (0)| 00:00:01 |     1 |     1 |      3 |00:00:00.01 |       3 |
|*  5 |      INDEX RANGE SCAN     | IX_DRS |      1 |      4 |    64 |     3   (0)| 00:00:01 |     1 |     1 |      3 |00:00:00.01 |       3 |
|   6 |     PARTITION RANGE SINGLE|        |      1 |    536 |  8576 |     7   (0)| 00:00:01 |     2 |     2 |     19 |00:00:00.01 |       7 |
|*  7 |      INDEX RANGE SCAN     | IX_DRS |      1 |    536 |  8576 |     7   (0)| 00:00:01 |     2 |     2 |     19 |00:00:00.01 |       7 |
|   8 |     PARTITION RANGE SINGLE|        |      1 |    929 | 14864 |    10   (0)| 00:00:01 |     3 |     3 |    890 |00:00:00.01 |      10 |
|*  9 |      INDEX RANGE SCAN     | IX_DRS |      1 |    929 | 14864 |    10   (0)| 00:00:01 |     3 |     3 |    890 |00:00:00.01 |      10 |
|  10 |     PARTITION RANGE SINGLE|        |      1 |     29 |   464 |     2   (0)| 00:00:01 |     4 |     4 |     17 |00:00:00.01 |       2 |
|* 11 |      INDEX RANGE SCAN     | IX_DRS |      1 |     29 |   464 |     2   (0)| 00:00:01 |     4 |     4 |     17 |00:00:00.01 |       2 |
|  12 |     PARTITION RANGE SINGLE|        |      1 |     84 |  1344 |     2   (0)| 00:00:01 |     5 |     5 |     14 |00:00:00.01 |       6 |
|* 13 |      INDEX FAST FULL SCAN | IX_DRS |      1 |     84 |  1344 |     2   (0)| 00:00:01 |     5 |     5 |     14 |00:00:00.01 |       6 |
----------------------------------------------------------------------------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------

   5 - access("END_DATE">=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss') AND "END_DATE"<=TO_DATE(' 2012-02-01 00:15:00',
              'syyyy-mm-dd hh24:mi:ss') AND "BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
       filter("BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
   7 - access("END_DATE">=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss') AND "END_DATE"<=TO_DATE(' 2012-02-03 00:00:00',
              'syyyy-mm-dd hh24:mi:ss') AND "BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
       filter("BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
   9 - access("END_DATE">=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss') AND "END_DATE"<=TO_DATE(' 2012-03-12 00:00:00',
              'syyyy-mm-dd hh24:mi:ss') AND "BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
       filter("BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
  11 - access("END_DATE">=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss') AND "END_DATE"<=TO_DATE(' 2013-03-07 00:00:00',
              'syyyy-mm-dd hh24:mi:ss') AND "BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
       filter("BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
  13 - filter(("BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss') AND "END_DATE">=TO_DATE(' 2012-02-01 00:00:00',
              'syyyy-mm-dd hh24:mi:ss')))

This approach reduces logical reads (LIOs) to 28, compared to the 183 in the best case from the previous parts.

Simplifying with a SQL Macro

To avoid writing such large queries repeatedly, we can create a SQL Macro:

create or replace function DRS_by_date_macro(dt date)
  return varchar2 sql_macro
is
begin
  return q'{
  select * from Dynamic_Range_Segmentation partition (part_15_min) p1
  where dt between beg_date and end_date
    and end_date<=dt+interval'15'minute
  union all
  select * from Dynamic_Range_Segmentation partition (part_2_days) p1
  where dt between beg_date and end_date
    and end_date<=dt+2
  union all
  select * from Dynamic_Range_Segmentation partition (part_40_days) p1
  where dt between beg_date and end_date
    and end_date<=dt+40
  union all
  select * from Dynamic_Range_Segmentation partition (part_400_days) p1
  where dt between beg_date and end_date
    and end_date<=dt+400
  union all
  select * from Dynamic_Range_Segmentation partition (p_max) p1
  where dt between beg_date and end_date
  }';
end;
/

With this macro, queries become concise:

SQL> select count(*),min(beg_date),max(end_date) from DRS_by_date_macro(date'2012-02-01');

  COUNT(*) MIN(BEG_DATE)       MAX(END_DATE)
---------- ------------------- -------------------
       943 2011-01-03 00:00:00 2013-03-03 00:00:00

Execution plan:

SQL> select * from table(dbms_xplan.display_cursor('','','all allstats last -alias -projection'));

PLAN_TABLE_OUTPUT
---------------------------------------------------------------------------------------------------------------------------------------
SQL_ID  7nmx3cnwrmd0c, child number 0
-------------------------------------
select count(*),min(beg_date),max(end_date) from
DRS_by_date_macro(date'2012-02-01')

Plan hash value: 1181465968

---------------------------------------------------------------------------------------------------------------------------------------
| Id  | Operation                 | Name   | Starts | E-Rows s| Cost (%CPU)| E-Time   | Pstart| Pstop | A-Rows |   A-Time   | Buffers |
---------------------------------------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT          |        |      1 |         |    24 (100)|          |       |       |      1 |00:00:00.01 |      28 |
|   1 |  SORT AGGREGATE           |        |      1 |      1  |            |          |       |       |      1 |00:00:00.01 |      28 |
|   2 |   VIEW                    |        |      1 |   1582  |    24   (0)| 00:00:01 |       |       |    943 |00:00:00.01 |      28 |
|   3 |    UNION-ALL              |        |      1 |         |            |          |       |       |    943 |00:00:00.01 |      28 |
|   4 |     PARTITION RANGE SINGLE|        |      1 |      4  |     3   (0)| 00:00:01 |     1 |     1 |      3 |00:00:00.01 |       3 |
|*  5 |      INDEX RANGE SCAN     | IX_DRS |      1 |      4  |     3   (0)| 00:00:01 |     1 |     1 |      3 |00:00:00.01 |       3 |
|   6 |     PARTITION RANGE SINGLE|        |      1 |    536  |     7   (0)| 00:00:01 |     2 |     2 |     19 |00:00:00.01 |       7 |
|*  7 |      INDEX RANGE SCAN     | IX_DRS |      1 |    536  |     7   (0)| 00:00:01 |     2 |     2 |     19 |00:00:00.01 |       7 |
|   8 |     PARTITION RANGE SINGLE|        |      1 |    929  |    10   (0)| 00:00:01 |     3 |     3 |    890 |00:00:00.01 |      10 |
|*  9 |      INDEX RANGE SCAN     | IX_DRS |      1 |    929  |    10   (0)| 00:00:01 |     3 |     3 |    890 |00:00:00.01 |      10 |
|  10 |     PARTITION RANGE SINGLE|        |      1 |     29  |     2   (0)| 00:00:01 |     4 |     4 |     17 |00:00:00.01 |       2 |
|* 11 |      INDEX RANGE SCAN     | IX_DRS |      1 |     29  |     2   (0)| 00:00:01 |     4 |     4 |     17 |00:00:00.01 |       2 |
|  12 |     PARTITION RANGE SINGLE|        |      1 |     84  |     2   (0)| 00:00:01 |     5 |     5 |     14 |00:00:00.01 |       6 |
|* 13 |      INDEX FAST FULL SCAN | IX_DRS |      1 |     84  |     2   (0)| 00:00:01 |     5 |     5 |     14 |00:00:00.01 |       6 |
---------------------------------------------------------------------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------

   5 - access("END_DATE">=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss') AND "END_DATE"<=TO_DATE(' 2012-02-01 00:15:00',
              'syyyy-mm-dd hh24:mi:ss') AND "BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
       filter("BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
   7 - access("END_DATE">=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss') AND "END_DATE"<=TO_DATE(' 2012-02-03 00:00:00',
              'syyyy-mm-dd hh24:mi:ss') AND "BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
       filter("BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
   9 - access("END_DATE">=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss') AND "END_DATE"<=TO_DATE(' 2012-03-12 00:00:00',
              'syyyy-mm-dd hh24:mi:ss') AND "BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
       filter("BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
  11 - access("END_DATE">=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss') AND "END_DATE"<=TO_DATE(' 2013-03-07 00:00:00',
              'syyyy-mm-dd hh24:mi:ss') AND "BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
       filter("BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))
  13 - filter(("BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss') AND "END_DATE">=TO_DATE(' 2012-02-01 00:00:00',
              'syyyy-mm-dd hh24:mi:ss')))
Conclusion and Next Steps

This approach can also be implemented in various ways, such as using materialized views, globally partitioned indexes, or other methods.

In the next part, I will demonstrate how to create a custom domain index to further optimize this method.

Categories: Development

Interval Search: Optimizing Date Range Queries – Part 1

XTended Oracle SQL - Wed, 2024-12-18 21:37

One of the most common and enduring challenges in database management is performing efficient interval searches, particularly for date intervals such as: WHERE :dt BETWEEN beg_date AND end_date.

In this series of articles, I will explore various strategies for optimizing such searches. We’ll delve into well-known standard approaches, analyze their limitations, and introduce my custom method—a method I promised to share several years ago, but I had postponed writing about it because the topic’s complexity seemed daunting, requiring a deep dive into the nuances of the data itself (e.g., open intervals, extreme values, data distribution, and skew). However, after receiving yet another question about it recently, I realized that I could no longer delay. Even if it means addressing some of the finer details in later parts, it’s time to start sharing this method in manageable steps.

Defining the Problem

In many applications involving historical data, a common modeling approach is SCD (Slowly Changing Dimension) Type 2 (reference). This method often uses columns such as begin_date and end_date to represent the validity period of each record.

To find records that are valid at a specific point in time, queries often use predicates like:
WHERE :dt BETWEEN beg_date AND end_date

The challenge lies in finding a universal and efficient method to execute such queries.

Solution Approaches

Let’s begin by creating a test table and generating sample data for evaluation:

create table test_table(
   beg_date date
  ,end_date date
  ,padding  varchar2(10)
);
declare
  procedure p_insert(
    start_date       date
   ,end_date         date
   ,step_minutes     number
   ,duration_minutes number
  ) is
  begin
    insert/*+ append */ into test_table(beg_date,end_date,padding)
    select 
      start_date + n * numtodsinterval(step_minutes,'minute')
     ,start_date + n * numtodsinterval(step_minutes,'minute') + numtodsinterval(duration_minutes,'minute')
     ,'0123456789'
    from xmltable('0 to xs:integer(.)' 
          passing ceil( (end_date - start_date)*24*60/step_minutes)
          columns n int path '.'
         );
    commit;
  end;
begin
  -- 5 min intervals every 5 minutes: 00:00-00:15, 00:05-00:20,etc:
  --p_insert(date'2000-01-01',sysdate, 5, 5);
  -- 5 min intervals every 5 minutes starting from 00:02 : 00:02-00:07, 00:07-00:12,etc
  p_insert(date'2000-01-01'+interval'2'minute,sysdate, 5, 5);
  -- 15 min intervals every 5 minutes: 00:00-00:15, 00:05-00:20,etc:
  p_insert(date'2000-01-01',sysdate, 5, 15);
  -- 30 min intervals every 15 minutes: 00:00-00:30, 00:15-00:45,etc:
  p_insert(date'2000-01-01',sysdate, 15, 30);
  -- 1 hour intervals every 15 minutes: 00:00-01:00, 00:15-01:15,etc:
  p_insert(date'2000-01-01',sysdate, 15, 60);
  -- 2 hour intervals every 20 minutes: 00:00-02:00, 00:20-02:00,etc:
  p_insert(date'2000-01-01',sysdate, 20, 120);
  -- 7 days intervals every 60 minutes:
  p_insert(date'2000-01-01',sysdate, 60, 7*24*60);
  -- 30 days intervals every 1 hour:
  p_insert(date'2000-01-01',sysdate, 60, 30*24*60);
  -- 120 days intervals every 7 days:
  p_insert(date'2000-01-01',sysdate, 7*24*60, 120*24*60);
  -- 400 days intervals every 30 days:
  p_insert(date'2000-01-01',sysdate, 30*24*60, 400*24*60);
end;
/

We’ve got a table with 10mln rows with different date intervals:

SQL> select count(*),min(beg_date),max(end_date) from test_table;

  COUNT(*) MIN(BEG_DATE)       MAX(END_DATE)
---------- ------------------- -------------------
  10723261 2000-01-01 00:00:00 2026-01-24 00:00:00
1. Simple Composite Indexes 1.1 Index on (beg_date, end_date)

The most straightforward approach is to create a composite index on (beg_date, end_date). However, even at first glance, it’s clear that this method has significant inefficiencies.

When we use a predicate like :dt BETWEEN beg_date AND end_date, it breaks down into two sub-predicates:

Access Predicate: beg_date <= :dt
This is used for index access since beg_date is the leading column in the index. However, the query will need to scan and evaluate all index entries that satisfy this condition.

Filter Predicate: :dt <= end_date
This acts as a filter on the results from the access predicate.

As the dataset grows, both beg_date and end_date values increase over time. Consequently, because the access predicate (beg_date <= :dt) is used to locate potential matches, the query will scan an ever-growing portion of the index.

1.2 Index on (end_date, beg_date)

This is one of the most widely adopted approaches. By simply rearranging the order of columns in the index, placing end_date first, we can achieve significantly better performance in most cases.

Why? Queries tend to target data closer to the current time, and much less frequently target records from far in the past. By indexing on end_date first, the query engine can more effectively narrow down the relevant portion of the index.

Let’s create the indexes and assess their performance:

create index ix_beg_end on test_table(beg_date,end_date);
create index ix_end_beg on test_table(end_date,beg_date);

select segment_name,blocks,bytes/1024/1024 as mbytes 
from user_segments 
where segment_name in ('IX_BEG_END','IX_END_BEG','TEST_TABLE');

SEGMENT_NAME             BLOCKS     MBYTES
-------------------- ---------- ----------
IX_BEG_END                40960        320
IX_END_BEG                40832        319
TEST_TABLE                48128        376

Let’s query the records valid 100 days ago using the (beg_date, end_date) index:

SQL> select/*+ index(test_table (beg_date,end_date)) */ count(*),min(beg_date),max(end_date) from test_table where sysdate-100 between beg_date and end_date;

  COUNT(*) MIN(BEG_DATE)       MAX(END_DATE)
---------- ------------------- -------------------
       935 2023-08-28 00:00:00 2025-09-26 00:00:00

SQL> select * from table(dbms_xplan.display_cursor('','','all allstats last'));


Plan hash value: 1056805589

--------------------------------------------------------------------------------------------------------------------------
| Id  | Operation         | Name       | Starts | E-Rows |E-Bytes| Cost (%CPU)| E-Time   | A-Rows |   A-Time   | Buffers |
--------------------------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT  |            |      1 |        |       | 40375 (100)|          |      1 |00:00:00.79 |   40200 |
|   1 |  SORT AGGREGATE   |            |      1 |      1 |    16 |            |          |      1 |00:00:00.79 |   40200 |
|*  2 |   INDEX RANGE SCAN| IX_BEG_END |      1 |  28472 |   444K| 40375   (1)| 00:00:02 |    935 |00:00:00.79 |   40200 |
--------------------------------------------------------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------

   2 - access("END_DATE">=SYSDATE@!-100 AND "BEG_DATE"<=SYSDATE@!-100)
       filter("END_DATE">=SYSDATE@!-100)

As seen, the query required 40,200 logical reads, almost the entire index, which contains 40,960 blocks.

Now, let’s query the same data using the (end_date, beg_date) index:

SQL> select count(*),min(beg_date),max(end_date) from test_table where sysdate-100 between beg_date and end_date;

  COUNT(*) MIN(BEG_DATE)       MAX(END_DATE)
---------- ------------------- -------------------
       935 2023-08-28 00:00:00 2025-09-26 00:00:00

SQL> select * from table(dbms_xplan.display_cursor('','','all allstats last'));

Plan hash value: 416972780

-------------------------------------------------------------------------------------------------------
| Id  | Operation         | Name       | Starts | E-Rows | Cost (%CPU)| A-Rows |   A-Time   | Buffers |
-------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT  |            |      1 |        |   450 (100)|      1 |00:00:00.01 |     453 |
|   1 |  SORT AGGREGATE   |            |      1 |      1 |            |      1 |00:00:00.01 |     453 |
|*  2 |   INDEX RANGE SCAN| IX_END_BEG |      1 |  28472 |   450   (1)|    935 |00:00:00.01 |     453 |
-------------------------------------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------

   2 - access("END_DATE">=SYSDATE@!-100 AND "END_DATE" IS NOT NULL)
       filter("BEG_DATE"<=SYSDATE@!-100)

Using this index required only 453 logical reads, a dramatic improvement compared to the 40,200 reads with the first index.

Adding an Upper Bound for end_date

To illustrate the importance of having both upper and lower bounds for effective range queries, let’s further restrict the query with end_date < SYSDATE - 70:

SQL> select count(*),min(beg_date),max(end_date) from test_table where sysdate-100 between beg_date and end_date and end_date<sysdate-70;

  COUNT(*) MIN(BEG_DATE)       MAX(END_DATE)
---------- ------------------- -------------------
       910 2023-08-28 00:00:00 2024-10-08 02:00:00

SQL> select * from table(dbms_xplan.display_cursor('','','all allstats last'));

Plan hash value: 3937277202

-----------------------------------------------------------------------------------------------
| Id  | Operation          | Name       | Starts | Cost (%CPU)| A-Rows |   A-Time   | Buffers |
-----------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT   |            |      1 |   136 (100)|      1 |00:00:00.01 |     137 |
|   1 |  SORT AGGREGATE    |            |      1 |            |      1 |00:00:00.01 |     137 |
|*  2 |   FILTER           |            |      1 |            |    910 |00:00:00.01 |     137 |
|*  3 |    INDEX RANGE SCAN| IX_END_BEG |      1 |   136   (0)|    910 |00:00:00.01 |     137 |
-----------------------------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------

   2 - filter(SYSDATE@!-70>SYSDATE@!-100)
   3 - access("END_DATE">=SYSDATE@!-100 AND "END_DATE"<SYSDATE@!-70 AND "BEG_DATE"<=SYSDATE@!-100)
       filter("BEG_DATE"<=SYSDATE@!-100)

We retrieved nearly all required records (910 out of 935), but the number of logical I/O operations (LIO) dropped by more than threefold.

To illustrate the inherent limitations of our current indexing strategies, let’s simplify the scenario. Suppose we have a table of integer intervals (START, END) containing 10 million records: (0,1), (1,2), (2,3), …, (9999999, 10000000). When searching for a record where 5000000 BETWEEN START AND END, regardless of whether we use an index on (START, END) or (END, START), we would have to scan approximately half of the index. This clearly demonstrates that neither of these indexes can serve as a universal solution; under certain conditions, both indexes become inefficient.

Let’s illustrate this issue using our test table. We’ll select a date roughly in the middle of our dataset – date’2012-02-01′ – and examine the performance of both indexes.

First, we’ll test the query using the (beg_date, end_date) index:

SQL> select/*+ index(test_table (beg_date,end_date)) */ count(*),min(beg_date),max(end_date) from test_table where date'2012-02-01' between beg_date and end_date;

  COUNT(*) MIN(BEG_DATE)       MAX(END_DATE)
---------- ------------------- -------------------
       943 2011-01-03 00:00:00 2013-03-03 00:00:00

SQL> select * from table(dbms_xplan.display_cursor('','','all allstats last -alias -projection'));

Plan hash value: 1056805589

--------------------------------------------------------------------------------------------------------
| Id  | Operation         | Name       | Starts | E-Rows | Cost (%CPU)|| A-Rows |   A-Time   | Buffers |
--------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT  |            |      1 |        | 19355 (100)||      1 |00:00:00.45 |   19680 |
|   1 |  SORT AGGREGATE   |            |      1 |      1 |            ||      1 |00:00:00.45 |   19680 |
|*  2 |   INDEX RANGE SCAN| IX_BEG_END |      1 |   2783K| 19355   (1)||    943 |00:00:00.45 |   19680 |
--------------------------------------------------------------------------------------------------------

The query required almost 20,000 LIO operations, a significant portion of the total index size. Next, we’ll perform the same query using the (end_date, beg_date) index:

select/*+ index(test_table (end_date,beg_date)) */ count(*),min(beg_date),max(end_date) from test_table where date'2012-02-01' between beg_date and end_date;

  COUNT(*) MIN(BEG_DATE)       MAX(END_DATE)
---------- ------------------- -------------------
       943 2011-01-03 00:00:00 2013-03-03 00:00:00

-------------------------------------------------------------------------------------------------------
| Id  | Operation         | Name       | Starts | E-Rows | Cost (%CPU)| A-Rows |   A-Time   | Buffers |
-------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT  |            |      1 |        | 20929 (100)|      1 |00:00:00.38 |   20973 |
|   1 |  SORT AGGREGATE   |            |      1 |      1 |            |      1 |00:00:00.38 |   20973 |
|*  2 |   INDEX RANGE SCAN| IX_END_BEG |      1 |    655K| 20929   (1)|    943 |00:00:00.38 |   20973 |
-------------------------------------------------------------------------------------------------------

Similarly, this query also required approximately 20,000 LIO operations, illustrating that both indices suffer from similar inefficiencies for this type of query.

The high number of logical reads in both cases highlights that neither index provides an efficient solution for queries with dates in the middle of the data range. The database engine must scan a large portion of the index to find the matching records, resulting in increased I/O and slower query performance, especially when the search value lies in the middle of the data range.

2. Partitioning + Composite Indexes

This approach is far less common but offers significant advantages. In the previous examples with composite indexes, the predicate on the second column of the index did not help reduce the number of scanned index entries. However, by partitioning the table on this second column, we can leverage partition pruning to exclude irrelevant partitions, significantly reducing the scan scope.

Example: Partitioned Table by END_DATE

To demonstrate, let’s create a partitioned table using the same data as in the previous example, partitioned by END_DATE on a yearly interval:

create table test_table_part_1(
   beg_date date
  ,end_date date
  ,rid rowid
)
partition by range(end_date) interval (numtoyminterval(1,'year'))
(
   partition part_01 values less than (date'2000-01-01')
);
insert/*+append parallel(4) */ into test_table_part_1
select beg_date,end_date,rowid from test_table;

create index ix_tt_part_local on test_table_part_1(beg_date,end_date) local;
call dbms_stats.gather_table_stats('','test_table_part_1');

This results in 28 partitions:

SQL> select partition_name,partition_position,blevel,leaf_blocks,num_rows from user_ind_partitions where index_name='IX_TT_PART_LOCAL';

PARTITION_NAME PARTITION_POSITION     BLEVEL LEAF_BLOCKS   NUM_ROWS
-------------- ------------------ ---------- ----------- ----------
PART_01                         1          0           0          0
SYS_P8333                       2          2        1621     429547
SYS_P8341                       3          2        1621     429304
SYS_P8348                       4          2        1621     429304
SYS_P8353                       5          2        1621     429304
SYS_P8355                       6          2        1625     430480
SYS_P8332                       7          2        1621     429304
SYS_P8335                       8          2        1621     429305
SYS_P8331                       9          2        1621     429305
SYS_P8336                      10          2        1625     430480
SYS_P8338                      11          2        1621     429304
SYS_P8340                      12          2        1621     429304
SYS_P8343                      13          2        1621     429304
SYS_P8345                      14          2        1625     430481
SYS_P8347                      15          2        1621     429305
SYS_P8352                      16          2        1621     429304
SYS_P8350                      17          2        1621     429304
SYS_P8351                      18          2        1625     430480
SYS_P8334                      19          2        1621     429305
SYS_P8337                      20          2        1621     429304
SYS_P8339                      21          2        1621     429305
SYS_P8342                      22          2        1625     430480
SYS_P8344                      23          2        1621     429304
SYS_P8346                      24          2        1621     429304
SYS_P8349                      25          2        1621     429305
SYS_P8354                      26          2        1561     413443
SYS_P8356                      27          1           2        391
SYS_P8357                      28          0           1          1

Let’s test the same query for the same DATE '2012-02-01' using the partitioned table:

SQL> select/*+ index(t (beg_date,end_date)) */ count(*),min(beg_date),max(end_date) from test_table_part_1 t where date'2012-02-01' between beg_date and end_date;

  COUNT(*) MIN(BEG_DATE)       MAX(END_DATE)
---------- ------------------- -------------------
       943 2011-01-03 00:00:00 2013-03-03 00:00:00

SQL> select * from table(dbms_xplan.display_cursor('','','all allstats last -alias -projection'));

Plan hash value: 1651658810

-------------------------------------------------------------------------------------------------------------------------------------
| Id  | Operation                 | Name             | Starts | E-Rows | Cost (%CPU)| Pstart| Pstop | A-Rows |   A-Time   | Buffers |
-------------------------------------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT          |                  |      1 |        | 10259 (100)|       |       |      1 |00:00:00.01 |     183 |
|   1 |  SORT AGGREGATE           |                  |      1 |      1 |            |       |       |      1 |00:00:00.01 |     183 |
|   2 |   PARTITION RANGE ITERATOR|                  |      1 |   2783K| 10259   (1)|    14 |1048575|    943 |00:00:00.01 |     183 |
|*  3 |    INDEX RANGE SCAN       | IX_TT_PART_LOCAL |     15 |   2783K| 10259   (1)|    14 |1048575|    943 |00:00:00.01 |     183 |
-------------------------------------------------------------------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------

   3 - access("END_DATE">=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss') AND "BEG_DATE"<=TO_DATE(' 2012-02-01 00:00:00',
              'syyyy-mm-dd hh24:mi:ss'))
       filter("END_DATE">=TO_DATE(' 2012-02-01 00:00:00', 'syyyy-mm-dd hh24:mi:ss'))

As shown, this approach reduced the number of logical reads (LIO) to just 183, compared to 20,000 in the earlier examples. Partitioning the table on END_DATE combined with a composite local index dramatically improves query performance by limiting the scan scope through partition pruning. Even in the worst-case scenario, the number of logical reads is orders of magnitude lower than with global composite indexes. This makes it a highly effective strategy for interval searches.

Next part: Interval Search: Part 2. Dynamic Range Segmentation – Simplified

Categories: Development

Top 10 Things to Consider in Securing an Oracle Database

Pete Finnigan - Wed, 2024-12-18 16:21
I presented recently at the UKOUG tech conference 2024 in Birmingham, UK at the Eastside rooms. This was a good conference and I had two talks there. This blog is about the first of those and includes a link to....[Read More]

Posted by Pete On 18/12/24 At 11:34 AM

Categories: Security Blogs

Nashville General Hospital Implements Oracle Health CommunityWorks to Simplify Clinician Experience, Enhance Patient Care

Oracle Press Releases - Wed, 2024-12-18 08:15

SOLVED - Cannot Log in Oracle cloud with 2FA after Phone Change with Oracle Mobile Authenticator

Pakistan's First Oracle Blog - Tue, 2024-12-17 17:27

 I have been logging in to Oracle cloud using multi-factor authentication using 2FA with Oracle Mobile Authenticator and it was going fine until I had to change my phone. Both of my phones are android and I THOUGHT that I will simply migrate the apps and keep  using the accounts in my Oracle mobile authenticator same way, but it seems that after migration I lost all the accounts. 

Multi-Factor Authentication (MFA) is a security process that requires a user to provide two or more authentication factors to access a system, network, or application. Two-Factor Authentication (2FA) is a type of Multi-Factor Authentication that requires a user to provide two authentication factors:

  • Something you know (password, PIN)
  • Something you have (smartphone, token, or a one-time password sent via SMS or authenticator app)

So I was using 2FA with this Oracle Mobile Authenticator. I tried with my older codes , QR codes, the password, PIN and stuff but nothing worked. No matter, what I tried I simply couldn't log in to Oracle Cloud since the page asked me for a code generated by the authenticator.

Eventually following is the only way I could find to resolve this issue:

I talked in Oracle live chat, and they asked me to find an engineer to send me a bypass code.

If you don't know what Oracle Mobile Authenticator app is then as per docs:

Oracle Mobile Authenticator enables you to securely verify your identity by using your mobile device as a authentication factor. The app generates one-time passwords for login. Or it can receive notifications for login, which can be approved with a simple tap. When this authentication is used on top of username-password, it adds an additional layer of security that is essential for today's online applications.

Features:

  • Generate one-time passwords even when the device is offline
  • Push Notification based approval
  • App PIN for app protection
  • Set up via QR code, Config URL, or by entering key manually
  • Multiple account support
  • Generate OTP for other applications that make use of One-Time Password as per RFC 6238
  • Generate one-time passwords even when the device is offline
  • Push Notification based approval
  • App PIN for app protection


I hope this helps.

Categories: DBA Blogs

Datetime.MaxValue timestamp ORA-01841

Tom Kyte - Tue, 2024-12-17 04:16
Hello, I've been struggling with "strange" behavior with handling "extreme " timestamp values. Our applications in .NET execute stored procedures with timestamp parameter and in some cases pass "31/12/9999 23:59:59.9999999" - it is value of Datetime.MaxValue function After upgrade to 19.25 we get "ORA-01841: (full) year must be between -4713 and +9999, and not be 0" for this value. Lets look on my examples Following statement returns same value for oracle 19.25 and < 19.25 versions <code>select to_timestamp('12/31/9999 23:59:59.9999999','MM/DD/YYYY HH24:MI:SS.FF') from dual;</code> 31-DEC-99 11.59.59.999999900 PM Lets create simple procedure <code> CREATE OR REPLACE PROCEDURE testmh( p_data in timestamp ) IS vdata timestamp(9); BEGIN dbms_output.put_line('a'); END; </code> and execute like <code>execute testmh(to_timestamp('12/31/9999 23:59:59.9999999','MM/DD/YYYY HH24:MI:SS.FF'));</code> on 19.25 I get ORA-01841: (full) year must be between -4713 and +9999, and not be 0 on < 19.25 PL/SQL procedure successfully completed. Another test - create the function <code> CREATE OR REPLACE FUNCTION testmhf ( p_data TIMESTAMP ) RETURN TIMESTAMP IS BEGIN RETURN p_data; END testmhf; </code> and execute <code>select testmhf(to_timestamp('12/31/9999 23:59:59.9999999','MM/DD/YYYY HH24:MI:SS.FF')) from dual;</code> for <19.25 result is 01-JAN-00 12.00.00.000000000 AM for 19.25 result is ORA-01841: (full) year must be between -4713 and +9999, and not be 0 Workaround for this problem is create the subtype and use that as type for procedure parameter <code> CREATE OR REPLACE PACKAGE XY AS SUBTYPE timestamp_t IS TIMESTAMP(7); END; / CREATE OR REPLACE PROCEDURE testmh_t( p_data in XY.timestamp_t ) IS BEGIN insert into zone(zone) values(p_data); END; / execute testmh_t(to_timestamp('12/31/9999 23:59:59.9999999','MM/DD/YYYY HH24:MI:SS.FF')); </code> Do you know any other workaround or why passing this "extreme" value is causing that this value is rounding up? M.
Categories: DBA Blogs

Streamlined Table Data Extraction with Sparrow | Table Transformer, Qwen2 VL, MLX, & Mac Mini M4 Pro

Andrejus Baranovski - Tue, 2024-12-17 02:08
Learn how to streamline table data extraction with Sparrow, Table Transformer, Qwen2 VL, and MLX on the Mac Mini M4 Pro. Simplify your workflow and get accurate results! 

 

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