All India Oracle User Group Events for 2018

Sangam 2018 is scheduled for 7th and 8th December 2018. I am presenting a session on “SQL Tuning ! Tips, Tools and Techniques” which is on 7th December 2018 and is immediately after Lunch. A 45 minute session doesn’t justify the topic, but will try my level best to cover few interesting real life examples. On 8th December, I will be co-hosting a Fire side chat on Performance along side Tirthankar Lahiri (VP of Product Management, Oracle US), Arup Nanda, GP Gongloor and Karan Dodwal. This is scheduled for 2.55 pm. The only issue is that I may have to leave early to catch my flight back to Mumbai.

North India Chapter – Chandigarh. Mark your calendar for 24th November 2018 as I will be speaking for the entire day on Performance Optimization covering some interesting topics around SQL Optimization, Optimizer, Indexes, Autonomous Databases and many more. This is a Full day event which gives me good amount of time to demonstrate some of the interesting facts. Registration for this event is open. Use the following link to register. See you soon.

https://www.meraevents.com/us/previewevent?view=preview&eventId=183767

For 2019, will publish the calendar, once it is freezed 🙂

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Importance of Constraints ! Know your Reporting Tools

Recently, I was working on a customer issue. The issue was a performance comparison between a Competition and an Oracle Database. The performance of Competition was reported to be better than Oracle. Now, this is a classic case of Bad Schema Design and a Badly Written Query. Working on this issue reminded me of a great learning that I had after reading “Expert Oracle Database Architecture” by Thomas Kyte. He wrote about a classic issue with a Pl/SQL Block running in SQL Server and generating wrong results when ported to Oracle Database due to the way these 2 databases compare NULL values. Each of these databases are different. It also reminded me of one of my response to a query from a customer on “A count(*) from a Table is doing a Full Table Scan, even though it has a Unique Index on it”.

As Tom mentioned in his book, every database is different and implement the features differently. Now, the third party tools that connect to each of these different data sources generate queries that syntactically work on all but may not run optimally. Therefore, it is important to understand our Data and design the Schema with all the required constraints and indexes in place.

In this case, customer was running few analytical reports from a Third Party Reporting Tool (Tableau). Customer selected few columns with couple of predicates with Date Range and some product name. The Queries were around 40-50 Lines. Surprisingly, for each of the Predicates, Tableau added few additional predicates and due to these additional predicates, the run time plan was around 2700+ lines long. As an example, I have a table T1 and have to generate a report selecting object id’s and names for any of the 2 TEMPORARY values (Y or N). My query will look like :

select object_id, object_name from t1 where temporary=:b1;

If I have an Index on TEMPORARY Column, Optimizer will come out with an optimal plan based on it’s cost calculation. However, when run from Tableau, it came out with the following query:

select object_id, object_name from t1
where ((temporary=:b1) or (temporary is NULL and :b1 is NULL));

What will be the implication of this added OR conditions ? Let’s see.

SQL> create table t1 as
select * from all_objects;  2

Table created.

SQL> exec dbms_stats.gather_table_stats(user,'T1', method_opt=>'for all columns size auto for columns temporary size 100');

PL/SQL procedure successfully completed.

SQL> create index t1_idx on t1(temporary);

Index created.

SQL> select num_rows, blocks from dba_tables where table_name='T1';

  NUM_ROWS     BLOCKS
---------- ----------
     68417       1375

SQL> variable l_temporary varchar2(1);
SQL> exec :l_temporary:='Y';

PL/SQL procedure successfully completed.

SQL> select object_id, object_name from t1
where ((temporary=:l_temporary) or (temporary is NULL and :l_temporary is NULL)); 

161 rows selected.

SQL> select * from dbms_xplan.display_cursor();

PLAN_TABLE_OUTPUT
------------------------------------------------------------------------------
SQL_ID  7xsahyu4q594y, child number 0
-------------------------------------
select object_id, object_name from t1 where ((temporary=:l_temporary)
or (temporary is NULL and :l_temporary is NULL))

Plan hash value: 3617692013

--------------------------------------------------------------------------
| Id  | Operation         | Name | Rows  | Bytes | Cost (%CPU)| Time     |
--------------------------------------------------------------------------
|   0 | SELECT STATEMENT  |      |       |       |   375 (100)|          |
|*  1 |  TABLE ACCESS FULL| T1   |   161 |  6923 |   375   (1)| 00:00:01 |
--------------------------------------------------------------------------

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

   1 - filter(("TEMPORARY"=:L_TEMPORARY OR ("TEMPORARY" IS NULL AND
              :L_TEMPORARY IS NULL)))

161 Rows out of 68000, which is less than 1%. Index Access would have been a better option. At customer end, the table was huge with Billions of Rows and with multiple such OR Predicates, the very first observation was the amount of time the Optimizer took to Parse the Query. The Query took around 184 Seconds to run and the observation was that out of 184 Seconds, around 175 Seconds were spent on Parsing. This was identified as a BUG in 18c (BUG#28725660) and the primary cause identified as the change in OR Expansion behaviour in 18c. This BUG is fixed in 19c. Backporting it to 18c would have taken some time, so the other fix that we applied was to add NOT NULL Constraints to some of the columns. From the Data, we could see that none of the columns had NULL values. We checked with the developers and they mentioned that NULL values are not stored in this column. Therefore, it was safe to add these constraints. Continuing with our example above, let’s add a NOT NULL constraint to our Table T1.

SQL> alter table t1 modify temporary not null;

Table altered.

select object_id, object_name from t1
where ((temporary=:l_temporary) or (temporary is NULL and :l_temporary is NULL));

select * from dbms_xplan.display_cursor();

PLAN_TABLE_OUTPUT
--------------------------------------------------------------------------------

Plan hash value: 1775246573

----------------------------------------------------------------------------------------------
| Id  | Operation                           | Name   | Rows  | Bytes | Cost (%CPU)| Time     |
----------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT                    |        |       |       |     5 (100)|          |
|   1 |  TABLE ACCESS BY INDEX ROWID BATCHED| T1     |   161 |  6923 |     5   (0)| 00:00:01 |
|*  2 |   INDEX RANGE SCAN                  | T1_IDX |   161 |       |     1   (0)| 00:00:01 |
----------------------------------------------------------------------------------------------

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

   2 - access("TEMPORARY"=:L_TEMPORARY)

The run time plan of the same query is now an Index Scan and is much better than previous. This additional input to the Optimizer was enough to transform the query. You can generate 10053 trace to see the transformation.

NOT NULL constraint combined with Unique Index is required to answer a COUNT(*) query from an Index, which one of my customer asked long time back. This is another case, where NOT NULL constraint helped optimizer come up with an optimal plan.

It is important to optimize the Schema and provide all the critical inputs to the Optimizer. Generic reporting tools would come out with queries that work on all the databases. These generated queries may work on some database and may not work on other. Therefore, the title of this blog “Know your Reporting Tool” :).

On the real customer issue, post adding the constraints to few of the columns, the query response time reduced drastically from 184 Seconds to less than 10 seconds far better than the competition.

Autonomous Database ! ADW and ATP. Why do I need both ?

Autonomous Data Warehouse (ADW) was announced in March 2018 and then Autonomous Transaction Processing (ATP) is the latest addition to the Autonomous Database family. ATP is for Mixed Workload and therefore provides 4 Service Names. These are :

HIGH :Highest level of CPU and IO Resources. Concurrency with this Service Name depends upon the number of OCPUs and will scale accordingly.

MEDIUM :Lowest level of CPU and IO Resources. Concurrency depends on the number of CPU’s and will scale accordingly.

LOW :Least amount of CPU and IO Resources. Again, Concurrency depends on the number of CPU’s and the Scaling is directly proportional to the number of OCPU’s.

ADW provides these three Service Names as well. However, unlike ADW (see my previous blog), the definition of these Services are different. In ADW, HIGH provides highest level of Resources but less concurrency, whereas, in ATP, HIGH do provide highest level of Resources but also provides Highest level of Concurrency. Since ATP is designed for Mixed Workload, it provides an additional Service Name PARALLEL. It provides high level of resources but lowest concurrency and is useful for Batch Processes or Heavy Reporting.

Now, many of the technical folks have raised this question on “Why do we need Both? Can’t we use ATP to take care of Data Warehouse kind of a load?”. ATP very well does that by providing an option to run Mixed Workload. However, there are many implementations that are purely Data Warehouse. The problem is that the amount of data that we generate, Warehouse Databases have grown massive in size supporting large amount of complex queries involving many nested joins and expecting sub-second response time. Further, these Databases house data from many different sources. Optimization Strategy for an OLTP and Data Warehouses are completely different. Therefore, an OLTP kind of a setup cannot (in most of the cases) provide the response time needed for DWH Queries.

Row Store v/s Columnar Store

Now, coming back to ATP v/s ADW argument. In an ADW, the data loaded is by default compressed to Oracle Hybrid Columnar Compression, whereas ATP uses a Row Store Format. What this means is that in an ADW, the data stored at disk is in a Columnar format, which is a proven format for speeding up Analytics kind of a Workload where we query few columns. All Data Warehouse Implementations, like Redshift, Google Big Query etc. store data in Columnar format. On the other hand, ATP stores the data in Row format which is ideal for OLTP that demands Single or few row(s) updates or deletes or queries small number of rows.

Since the data in ADW is stored Compressed in Columnar format, it allows scanning of Billions of Rows per CPU cycle. The data for a particular column is stored contiguously making it possible to scan through large number of rows in a single CPU cycles. This technique is called SIMD (Single Instruction Multiple Dataset) processing. To meet a sub-second response time, this technique is plays a significant role.

Such large scans (scanning billion of rows per second) is not possible with Row Store and one of the reasons for this can be found in one of my blog published in 2015 which is still very much relevant. Skipping of Columns consume CPU Cycles which is demonstrated in the blog post that can be found here.

Through this short blog, I wanted to clear the confusion around ADW and ATP. Both have their own use cases and thus are optimized to manage different workloads. Both of these Autonomous Databases have some exciting features. Stay tuned for more on these.

Resource Manager – Autonomous Data Warehouse

I recently presented a Full Day Tech Event on Autonomous databases (ADB) for the North India Chapter of All India Oracle User Group. Since most of the attendees were Database Administrators, it was important to cover technical aspects of ADB. While Oracle doesn’t publicize the Internals of ADB, I spoke about some of my experiences based on many of POC’s.

Many DBA’s still assume that 18c Database is Autonomous? Therefore it is Important to know What is Autonomous Database and What it is not? First thing to note is that 18c is not Autonomous. 18c is just like any other Oracle Database. Autonomous uses the features of Oracle Database 18c, plus 12c, plus 11g, plus 10g and so on. Autonomous Database ensures that all these features work together. So, 18c is one of the Building Blocks of 18c. Autonomous uses all the features that Oracle Developed for almost 2 decades. The other important underlying technology is Oracle Exadata, which is the fastest Oracle Database Machine with redundancy built-in at each layer. Again, Oracle had been working on many features that makes this machine a powerful database machine, in terms of Performance, Reliability and Scalability. The Journey had been long from Smart Scans to Direct-to-wire protocol to Smart Fusion Block Transfer and the enhancements continue. One important thing to note is – Customers do have an option to move to 18c on Exadata within their own Data Centre. Then does it mean, this combination is Autonomous? The answer is NO. The two components are critical, but what makes it Autonomous is the Cloud Automation with Machine Learning.

During the session, I covered the Performance features and the way Oracle controls resource utilization. The topic that came up was Oracle Database Resource Managers. Database Administrators were more inquisitive to know more about this and how it is been implemented in ADB.

Resource Manager-

Resource Managers or Consumer Groups or Service names are the integral part of Autonomous Databases as they manage the workload based on the performance characteristics of the Application. For example, in an Autonomous Data Warehouse there are 3 pre-created Service Names. These are –

HIGH – Highest Resources and Lowest Concurrency. Maximum Queries that can run are 3.

MEDIUM – Less Resources and High Concurrency. Maximum Queries would depend upon the number of OCPU’s.

LOW – Least resources and Highest Concurrency. Maximum Queries – twice the number of OCPU’s and therefore, would depend upon the number of OCPU’s.

Autonomous Transaction Processing (ATP) introduced a new Service – PARALLEL. In the context of ATP, the definition for HIGH, MEDIUM and LOW is different that in ADW. I will cover these in other blog post.

Now, the game becomes more interesting with HIGH and MEDIUM Consumer Groups. While the maximum number of Queries that can run from HIGH is 3 but with concurrency i.e. with concurrent Queries running from MEDIUM and LOW, this number can be less than 3. Same is the case with MEDIUM. With MEDIUM, the maximum numbers would depend on the number of OCPU’s, but actual concurrent queries that can run below the maximum allowed would depend upon the queries running from other consumer groups. For LOW, it is twice the number of OCPU’s and is irrespective of number of queries running from other consumer groups. All these are managed efficiently by pre-configured Resource Managers. Resource Manager, as the name implies, manages the resources. When the load on the system is light, there is very little need for managing the resources. However, as the load increases and system becomes more busy, managing the resources become more important. One of the Primary Goal of Autonomous Database is to ensure consistent performance (always). Therefore, these restrictions. However, as mentioned earlier, other than HIGH, the maximum for other consumer groups depends upon the number of OCPU’s. So, if you have a highly concurrent environment or during peak load with high concurrency, you can scale up more OCPU’s and scale down as well. By the way, Scaling OCPU’s UP and DOWN is Online and is irrespective of the Storage. Let me digress for a moment here. In case of Autonomous Database, if you need additional Storage, you can add it Online and this increase does not mandate adding OCPU’s. Same with the OCPU’s, you don’t need to add Storage. Both are independent. This is not the case with the competition. For example, with AWS Redshift or Microsoft SQL Data Warehouse, since these technologies work on Shared Nothing Architecture, additional Storage means adding more OCPU’s as well. What this means is – Even if you have good amount of CPU resources available and need is to add only the Storage, you will have to add a compute node as well. A storage without a compute is like a DEAD duck. It does nothing on disk unless connected to a Compute Mode.

Coming back to the Resource Manager. As mentioned, resource manager is automatically created and the Application owner has to only make sure that the application queries or the reports are connected to one of the consumer groups based on workload patterns or application requirements.

Why Resource Manager (RM)?

As mentioned earlier, the primary goal of a RM is to Manage System Resources. If resources were unlimited, there would be no need to manage them. Without these, all database connections are considered equal and under heavy load all sessions are impacted equally. There are various components of RM, like Consumer Groups – RM allocate resources to Consumer Groups and not to Sessions, Plan Directives – Resource allocations are actually assigned to Plan Directives and a Consumer group is then assigned a Directive, then finally Resource Plan – a collection of Directives that determines how the resources are to be allocated and managed. Resource Plan is set at the Database or System Level using RESOURCE_MANAGER_PLAN.

In terms of mapping rules, all user sessions (except SYS and SYSTEM) are mapped to a Consumer Group. By default, these are mapped to OTHER_GROUPS, which is a mandatory consumer group. There are 2 types of Session Attributes – Login Attributes and Runtime Attributes. Runtime Attributes is assigned at Runtime and can ne changed anytime during the life cycle of the session. This is basically decided by the application. Login Attributes is tied to the connection and cannot be changed during the lifecycle.

Resource Manager, in ADB uses Login Attribute. Therefore, the application connection is to a particular Service Name has to be pre-decided based on the application requirement.

The maximum number of Queries that can be executed using MEDIUM and LOW Service Names scales linearly. As per Oracle Documentation, for a 16 OCPU Machine, the maximum with MEDIUM is 20 and LOW is 32 (twice the number of OCPU’s). As you scale-up, say to 32 OCPU’s, the maximum for these will Scale as well to 40 for MEDIUM and 64 for LOW.

At present, will restrict this blog post to Resource Manager. Will write on something interesting soon.

Autonomous Database Tech Day ! Gurgaon

 

#Autonomous #AIOUG Presenting a Full Day Event on 8th September 2018 for North India Oracle User Group in Gurgaon. This is on Oracle Autonomous Database. Would be covering some interesting technical capabilities of Autonomous Databases. I am covering the 2 offerings i.e. Autonomous Data Warehouse and Autonomous Transaction Processing. For Registration, click on the following link :

Meraevents Link

This being an Oracle User Group Session, focus would be on the Technical Capabilities of ADW / ATP, like Parallel Processing, Concurrency, Optimizer Enhancements and Behaviour and most importantly, Competition.

So, North India Folks : See you all on 8th September 2018.

Autonomous Data Warehouse ! World Tour

Just came back from my first leg of Autonomous Data Warehouse World Tour. Met multiple customers in Bangalore who had come to attend the session that comprised of Keynote session followed by Technical details on Autonomous Data Warehouse. Second half was a Hands on Lab Session for the customers.

At the end, we had very good interaction with the customers with many interesting queries around this Service. Many of them were keen to know the difference between Autonomous Data Warehouse and the Competition. Will surely post a blog on this.

As a Technical Expert, I can only say “Try it out to believe the level of simplicity that ADWC brings in to give you a powerful Data Warehouse experience”. If you have a Data Warehouse and want to try ADWC, do connect with me.

My next destination is Sydney.

Oracle Autonomous Database ! World’s First Autonomous Database

Sangam 2017 was a great hit with around 800+ attendees. The Organizers did a great job in managing the show effectively. As mentioned in my earlier post, this year I presented sessions on “Indexing : Facts and Myth” on 8th December and “Autonomous Database” on 9th December. Apart from these, I also hosted a “Fireside Chat on Database/Application Performance” along with other speakers including Tirthankar Lahiri, VP for Oracle In-Memory Technologies Product Management. Andrew Holdsworth, VP for Oracle Real World Performance joined us as well. Together, we could address some of the queries raised by the participants of this Fire side chat. We had around 100+ attendees for the fire side chat.

While there is always a demand for a technical session and I rightly guessed a descent crowd for my Indexing Session. However, I was surprised to see a full house (around 200+) attendance for the session on Autonomous Database. This clearly means that the Technical Community wanted to know more about this interesting new technology, which is world’s first Autonomous Database. The session was very interactive and I tried responding to many of the queries, including the top most concern on the DBA Role.

My presentation kicked off with a Q&A on some of the Automated Features Oracle introduced since Oracle 9i. In my opinion, Automatic Segment Space Management (ASSM) introduced in Oracle 9i was the very first self-tuning feature as it dynamically adapts to (re)configuration of RAC Nodes without any changes required. This shows that Oracle’s journey to Autonomous Database started more than a Decade ago. Remember, Oracle 9i was released in 2001. Since then, Oracle introduced many features that reduced the burden off the DBA’s. All these features had one thing in common – AUTOMATIC. Automation is obviously one of the key drivers when it comes to Autonomous Database.

During the session, I also discussed about the difference between Automatic and Autonomous. Many organizations has introduced some or the other Automation to reduce or eliminate some of the mundane tasks. Certain amount of Automation can be done, however, to make a critical database entirely Autonomous, Full end-to-end Automation that too Automation of Complex tasks is required.

The underlying database for Autonomous DB is Oracle 18c. However, many were confused that Oracle 18c is an Autonomous Database. Therefore, it is important to know that Oracle 18c alone is not an Autonomous Database.

Autonomous Database = Oracle 18c + Oracle Cloud Automation and Innovation + Secret Sauce

So, Autonomous Database is made up of multiple component. The core underlying database version is 18c, which is integrated with Oracle Cloud and then uses some specialized tooling and automation that Oracle has created on cloud and some of them developed over the years. Machine Learning algorithm is used at every layer to make it more proactive.

Exadata has been a proven innovation when it comes to running an Oracle Database. Autonomous Database runs on Exadata, which further provides a healthy, highly available and best performance database for any kind of workload.

I can write more about Autonomous Database, but would want to hold for some other part. Thought of writing on this, as it generated a huge interest during Sangam and this excited me a lot. 🙂

Would be happy to respond to any of the queries related to Autonomous Database.

Sangam 2017 ! Largest Annual Event of All India Oracle User Group

Sangam, India’s largest All India Oracle User Group Event is back and this time in Hyderabad. Oracle experts across the globe would be speaking and therefore, this is the best opportunity to learn from them and collaborate with other Oracle professionals.

I will be presenting 2 sessions and will be hosting a “Fireside Chat with Performance Tuning Experts” round table discussions. Along side me, there would be Tirthankar Lahiri, VP-Product Management for In-Memory Technologies, Oracle, Karan Dodwal and Kishore Surve.

Oracle Autonomous Database is one of the most talked about technology and many of you would be eager to know more about it. I will be speaking on Autonomous Database on 9th December 2017. At present, it is scheduled for 2 pm India Time. Please do check the schedule, as it can change. Seats are limited. Therefore, to avoid disappointment, kindly book your seats in advance.

Another session of mine is on “Indexing : Facts and Myths”. This session will walk you through some of the common myths and few facts. A must attend session for Technical Folks. Again, due to the limited capacity, it is better to book your seat in advance. This is scheduled for 8th December 2017.

On 9th December 2017, join me and other Oracle Experts for a fireside chat on performance. Bring your questions and get response from the experts. Performance queries are difficult to address without some data or artifacts. If you can carry some of these, that would help us further and the chat would me more meaningful.

See you in Hyderabad on 8th December.

Index – Ordering of Columns

Post my previous Blog on Consistent Gets for an Index Scan, there were few other queries that I received over the chat. The queries were related to Clustering Factor of an Index and therefore, the recommendation or comment was that the Columns should be ordered to keep the value of a Clustering Factor as low as possible. The other comment was that High Cardinality or Low Cardinality plays a critical role with an exception for Unique or Primary Key Indexes. Again, Clustering Factor was cited as the reason behind this comment. Thought of clarifying this as well. In my opinion, this is again a MYTH.

The myth that I am going to address here is – Indexes and Column Ordering should be designed such that the Clustering Factor is as low as possible. This means, an Index on (B,A) should be preferred than (A,B) if the clustering factor of (A,B) is higher than (B,A).

Assuming, I have application queries, like :

select C, D from TABLE_A where A=:b1;

select C, D from TABLE_A where B=:b1 and A=:b2;

If I go by the above myth, shall I then create an Index on (B,A) ? Will this index be used for Query#1 ? Remember, Index Skip Scan is an Optimizer decision and is chosen if the leading column is a low cardinality column. The definition of low cardinality would be an Optimizer decision based on the costing. If an index on (B,A) is not used by Query#1, then shall I go ahead and create another Index on A ? Indexes improve query performance but are overhead for DML’s and therefore, less the number of Indexes, better the DML performance would be. Further, if a column is badly clustered, whether it is a leading column or a trailing column, it doesn’t matter and we will see this with an example. Therefore, as I mentioned in earlier and in my previous blog, Column Ordering of an Index should be basis your application queries and should not be designed basis any other table or column level statistics.

In this case, I am creating a table VIVEK_TEST with 100K rows. Column BC stands for BAD_CLUSTERED and will dominate the clustering factor. There are other 2 columns of interest – Object_ID which is a non unique column and RNUM_UNQ which is a Unique Column.

exec dbms_random.seed(0);

create table vivek_test as
with test as
(select * from all_objects where rownum between 1 and 10000)
select  trunc((rownum-1)/1000) object_id,
	rownum	rnum_unq,
        round(dbms_random.value(1,100),0) bc,
        a.object_name,
        a.temporary,
        a.created
from    test a,
        test b
where  rownum between 1 and 10000;

exec dbms_stats.gather_table_stats(user,'VIVEK_TEST');

column owner for a30
select owner, num_rows, blocks from dba_tables where table_name='VIVEK_TEST';

OWNER                  NUM_ROWS     BLOCKS
-------------------- ---------- ----------
SCOTT                     10000         62

First, I will create 4 Indexes – 2 of these are Single Column Indexes and 2 are Multi-Column.

create index vivek_test_oid on vivek_test(object_id);
create index vivek_test_oid_bc on vivek_test(object_id, bc);
create index vivek_test_bc on vivek_test(bc);
create index vivek_test_bc_oid on vivek_test(bc,object_id);

column index_name for a30
select index_name, num_rows, blevel, leaf_blocks, distinct_keys, clustering_factor
from    dba_indexes
where   table_name='VIVEK_TEST'
order by 1;

INDEX_NAME                       NUM_ROWS     BLEVEL LEAF_BLOCKS DISTINCT_KEYS CLUSTERING_FACTOR
------------------------------ ---------- ---------- ----------- ------------- -----------------
VIVEK_TEST_BC                       10000          1          20           100              4642 <-- Single Column on BC (Bad_Clustered)
VIVEK_TEST_BC_OID                   10000          1          24          1000              4642 <-- BC is the Leading Column
VIVEK_TEST_OID                      10000          1          20            10                56
VIVEK_TEST_OID_BC                   10000          1          24          1000              4856 <-- BC is the Trailing Column

As seen in the example above, column ordering doesn’t matter when it comes to the Clustering Factor. My choice of Indexing would be :

VIVEK_TEST_BC_OID if most of my queries are on 
	BC=:b1;
	BC =:b1 and object_id=:b2;

VIVEK_TEST_OID_BC if most of my queries are on 
	object_id=:b1;
	BC=:b1 and object_id=:b2;

Now, I will drop these indexes and create new indexes on the combination of BC and RNUM_UNQ. RNUM_UNQ is 100% Unique Column.

create index vivek_test_rnum on vivek_test(rnum_unq);
create index vivek_test_rnum_bc on vivek_test(rnum_unq, bc);
create index vivek_test_bc on vivek_test(bc);
create index vivek_test_bc_rnum on vivek_test(bc, rnum_unq);


column index_name for a30
select index_name, num_rows, blevel, leaf_blocks, distinct_keys, clustering_factor
from    dba_indexes
where   table_name='VIVEK_TEST'
order by 1;

INDEX_NAME                       NUM_ROWS     BLEVEL LEAF_BLOCKS DISTINCT_KEYS CLUSTERING_FACTOR
------------------------------ ---------- ---------- ----------- ------------- -----------------
VIVEK_TEST_BC                       10000          1          20           100              4642 <-- Single Column on BC (Bad_Clustered)
VIVEK_TEST_BC_RNUM                  10000          1          26         10000              4642 <-- Leading Column dominates CF
VIVEK_TEST_RNUM                     10000          1          21         10000                56
VIVEK_TEST_RNUM_BC                  10000          1          26         10000                56

For an Index with a Column, either leading or trailing, with 100% Unique values, the leading column would dictate the calculation of Clustering Factor. This is obvious as for the Clustering factor calculation, the values are sorted on the first_column then on Second_Column. For a better idea of how is it calculated, you may run the following queries :

## CF Calculation for BC, RNUM_UNQ (it matches the value as per DBA_INDEXES)

select  sum(block_change) from (
select  block_fno, bc, RNUM_UNQ, prev_bfno,
        (case when nvl(prev_bfno,0)!=block_fno then 1 else 0 end) block_change from (
        select  block_fno, bc, RNUM_UNQ, lag(block_fno) over (order by bc, rnum_unq) prev_bfno from (
                select  dbms_rowid.rowid_block_number(rowid)||'.'||
                        dbms_rowid.ROWID_TO_ABSOLUTE_FNO(rowid,'&Schema','&table_name') block_fno,
                        bc, RNUM_UNQ
                from  VIVEK_TEST
                order by bc, RNUM_UNQ, block_fno)
        )
);

SUM(BLOCK_CHANGE)
-----------------
             4642


## CF Calculation for RNUM_UNQ, BC (it matches the value as per DBA_INDEXES)

select  sum(block_change) from (
select  block_fno, RNUM_UNQ, bc, prev_bfno,
        (case when nvl(prev_bfno,0)!=block_fno then 1 else 0 end) block_change from (
        select  block_fno, RNUM_UNQ, bc, lag(block_fno) over (order by rnum_unq, bc) prev_bfno from (
                select  dbms_rowid.rowid_block_number(rowid)||'.'||
                        dbms_rowid.ROWID_TO_ABSOLUTE_FNO(rowid,'&Schema','&table_name') block_fno,
                        bc, RNUM_UNQ
                from  VIVEK_TEST
                order by RNUM_UNQ, bc, block_fno)
        )
);

SUM(BLOCK_CHANGE)
-----------------
               56

This query can be further modified to get the calculation. Remove the SUM(BLOCK_CHANGE) SELECT from the query and you could generate the output with the calculation. For every Index Entry, if the table block is changed, the BLOCK_CHANGE value is set to 1. This query will help you understand the calculation. This holds true for a combination of Non-Unique columns as well. It is not that for column involving Unique Column, the calculation is different and this will be clear if you deep dive into the queries pasted above.

During my session, I also mentioned a FLAW in Clustering Factor. It is that it doesn’t take into consideration the caching effect and to address this, Oracle introduced TABLE_CACHED_BLOCKS preference. I am against setting manually setting clustering_factor to a lower value as it will be overwritten by the next statistics gathering process. Also, I am STRONGLY against CTAS using ORDER BY to improve the clustering_factor. By using CTAS, you can improve the clustering_factor of one index, but it will impact this for other indexes. The best way is to use the TABLE_CACHED_BLOCKS preference as depicted below.

I will use the queries pasted above to come out with the actual clustering_factor and will then set the TABLE_CACHED_BLOCKS preference. For demonstration, I will work on an Index on BC, RNUM_UNQ. This process can be used for any of the indexes.

## I will create a temporary table to hold the clustering_factor calculation


create table cluf_factor as
select bc, blkno,
        lag(blkno,1,blkno) over(order by bc) prev_blkno,
        case when blkno!=lag(blkno,1,blkno) over(order by bc) or rownum=1
           then 1 else null end cluf_ft from
(select bc, rnum_unq, dbms_rowid.rowid_block_number(rowid) blkno
from    VIVEK_TEST
where   BC is not null
order by bc);

compute sum of cnt on report
break on report
select blkno, count(*) cnt from cluf_factor group by blkno order by 1;

     BLKNO        CNT
---------- ----------
    255883        188
    255884        185
    255885        185
    255886        185
    255887        185
    255936        182
    255937        180
    255938        180
    255939        180
    255940        180
    255941        180
    255942        180
    255943        180
    255945        180
    255946        180
    255947        180
    255948        180
    255949        180
    255950        180
    255951        180
    258896        180
    258897        180
    258898        180
    258899        180
    258900        180
    258901        180
    258902        180
    258903        180
    258905        180
    258906        180
    258907        180
    258908        180
    258909        180
    258910        180
    258911        180
    260480        180
    260481        180
    260482        180
    260483        180
    260484        180
    260485        180
    260486        180
    260487        180
    260489        180
    260490        180
    260491        180
    260492        180
    260493        180
    260494        180
    260495        180
    260496        180
    260497        180
    260498        180
    260499        180
    260500        180
    260501         70
           ----------
sum             10000

56 rows selected.

As per the output, each of the block was touched around 180 times. Each of these touch were considered as it these were read from the Disk. However, Oracle purely works in Memory (Buffer_Cache, Shared_Pool etc) and once the block is read from disk, it is cached in the Buffer_cache thus avoiding the disk i/o. This flaw causes unwanted high clustering_factor and therefore, is addressed by way of TABLE_CACHED_BLOCKS.

TABLE_CACHED_BLOCKS value defaults to 1. Increasing this value (to, say 250) means, clustering_factor for an Index will not be incremented, if the table block being referenced by the current Index entry has been referenced by any of the previous 250 Index Entries. In our case, each of the table blocks were referenced by previous 180 index entries. Therefore, I will change this value to 180.

select index_name, leaf_blocks, clustering_factor from dba_indexes
where table_name = 'VIVEK_TEST';

INDEX_NAME                     LEAF_BLOCKS CLUSTERING_FACTOR
------------------------------ ----------- -----------------
VIVEK_TEST_RNUM                         21                56
VIVEK_TEST_RNUM_BC                      26                56
VIVEK_TEST_BC                           20              4642
VIVEK_TEST_BC_RNUM                      26              4642

select dbms_stats.get_prefs(pname=>'TABLE_CACHED_BLOCKS',ownname=>'SCOTT',tabname=>'VIVEK_TEST') preference from dual;

PREFERENCE
-----------------------------------------------------------
1

## Setting TABLE_CACHED_BLOCKS to 180
exec dbms_stats.set_table_prefs(ownname=>'SCOTT',tabname=>'VIVEK_TEST',pname=>'TABLE_CACHED_BLOCKS',PVALUE=>180);

select dbms_stats.get_prefs(pname=>'TABLE_CACHED_BLOCKS',ownname=>'SCOTT',tabname=>'VIVEK_TEST') preference from dual;

PREFERENCE
------------------------------------------------------------
180

exec dbms_stats.gather_table_stats(user,'VIVEK_TEST',method_opt=>'for all columns size 1', no_invalidate=>false);

select index_name, leaf_blocks, clustering_factor from dba_indexes
where table_name = 'VIVEK_TEST';

INDEX_NAME                     LEAF_BLOCKS CLUSTERING_FACTOR
------------------------------ ----------- -----------------
VIVEK_TEST_RNUM                         21                56
VIVEK_TEST_RNUM_BC                      26                56
VIVEK_TEST_BC                           20                56
VIVEK_TEST_BC_RNUM                      26                56

Clustering Factor is calculated for Unique Indexes as well and is critical for costing. The only time when clustering_factos is not considered or not relevant for Unique or Primary Keys is when querying for all the columns part of the Unique or Primary Key i.e. INDEX UNIQUE SCAN. However, clustering_factor will play a critical role when accessing the Unique or Primary Key using INDEX RANGE SCAN.

With this blog, I tried addressing following Myth’s –

- 	Indexes and Column Ordering should be designed such that the Clustering Factor is as low as possible. 
- 	Clustering_Factor is irrelevant for Unique and Primary Key Indexes.
-	High Cardinality or Low Cardinality play important roles with an exception for Unique & Primary Key.

Be it a Unique Index / Primary Key Index or any other Index, column ordering has to be basis your application queries.

One interesting fact on TABLE_CACHED_BLOCKS : While testing this, I actually created a table with 100k rows. The number of blocks in the table were around 469 and the table block were referenced by around 230 previous index entries. Therefore, I modified this preference to 230 and regathered the statistics. It didn’t work. The same table creation script with 10k rows, everything worked as expected. I am investigating this and will update the blog, once I have something to share.

Consistent Gets for an Index Scan

This question was raised by a participant during my User Group Session on “Indexing : Fact & Myth Session”. Therefore, I thought of writing about it with the same example that I demonstrated..

I was demonstrating on a Myth that “High Cardinality Column should be a Leading Column of an Index” and for this, I created following table with 2 Indexes.

create table t1 as
select * from all_objects;

exec dbms_stats.gather_table_stats(user,'T1');

SQL> select owner, num_rows, blocks from dba_tables where table_name='T1' and owner='SCOTT';

OWNER                  NUM_ROWS     BLOCKS
-------------------- ---------- ----------
SCOTT                     68605       1377

SQL> select column_name, num_distinct, num_nulls from dba_tab_columns
where   owner='SCOTT'
and     table_name='T1'
and     column_name in ('OBJECT_ID','TEMPORARY')
order by 1;

COLUMN_NAME                    NUM_DISTINCT  NUM_NULLS
------------------------------ ------------ ----------
OBJECT_ID                             68605          0
TEMPORARY                                 2          0

SQL> create index t1_ot on t1(object_id, temporary);

Index created.

SQL> create index t1_to on t1(temporary,object_id);

Index created.

SQL> select index_name, blevel, leaf_blocks, clustering_factor from dba_indexes
where   table_name='T1'
order by 1;

INDEX_NAME                         BLEVEL LEAF_BLOCKS CLUSTERING_FACTOR
------------------------------ ---------- ----------- -----------------
T1_OT                                   1         171              1458
T1_TO                                   1         171              1494

So, I have a table with 68605 rows. Object_ID is 100% Distinct and Temporary has 2 Distinct Values. I have 2 indexes on it, which are on object_id & temporary. T1_OT is on (Object_ID, Temporary) and T1_TO is on (Temporary, Object_ID). The naming convention stands for the first letter of the columns in the order they are in the Index. So, for T1_OT O->Object_id and T->Temporary.

The Index Statistics shows that the two indexes are almost same, in terms of Height (BLEVEL), number of Leaf Blocks. A minor different in the Clustering_factor though.

I than executed the queries to demonstrate that the I/O’s done by queries using any of the 2 indexes is exactly same. For this, I executed the query and it used Index T1_OT and and then hinted the query to make use of T1_TO Index. The Cost and IO’s for both the queries are exactly same, which leads to a conclusion that cardinality doesn’t matter when designing a Index Strategy. Index Columns should be based on Application Queries and the Columns. The queries were executed twice to ensure that the consistent gets that we are post the hard parsing.

## IO's for the Query using an Index T1_OT

select owner, object_name from t1
where      object_id = 58
and        temporary='N';

OWNER                OBJECT_NAME
-------------------- ------------------------------
SYS                  I_CCOL2

set autot trace
select owner, object_name from t1
where      object_id = 58
and        temporary='N';

Execution Plan
----------------------------------------------------------
Plan hash value: 3109227855

---------------------------------------------------------------------------------------------
| Id  | Operation                           | Name  | Rows  | Bytes | Cost (%CPU)| Time     |
---------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT                    |       |     1 |    48 |     2   (0)| 00:00:01 |
|   1 |  TABLE ACCESS BY INDEX ROWID BATCHED| T1    |     1 |    48 |     2   (0)| 00:00:01 |
|*  2 |   INDEX RANGE SCAN                  | T1_OT |     1 |       |     1   (0)| 00:00:01 |
---------------------------------------------------------------------------------------------

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

   2 - access("OBJECT_ID"=58 AND "TEMPORARY"='N')

Statistics
----------------------------------------------------------
          0  recursive calls
          0  db block gets
          4  consistent gets 
          0  physical reads
          0  redo size
...
...
          1  rows processed

## IO's with Index T1_TO

SQL> select /*+ index(t1,t1_to) */ owner, object_name from t1
     where      object_id = 58
     and        temporary='N';

OWNER                OBJECT_NAME
-------------------- ------------------------------
SYS                  I_CCOL2

Elapsed: 00:00:00.00
SQL> pause;

set autot trace
select /*+ index(t1,t1_to) */ owner, object_name from t1
where      object_id = 58
and        temporary='N';


Execution Plan
----------------------------------------------------------
Plan hash value: 1129381402

---------------------------------------------------------------------------------------------
| Id  | Operation                           | Name  | Rows  | Bytes | Cost (%CPU)| Time     |
---------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT                    |       |     1 |    48 |     2   (0)| 00:00:01 |
|   1 |  TABLE ACCESS BY INDEX ROWID BATCHED| T1    |     1 |    48 |     2   (0)| 00:00:01 |
|*  2 |   INDEX RANGE SCAN                  | T1_TO |     1 |       |     1   (0)| 00:00:01 |
---------------------------------------------------------------------------------------------

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

   2 - access("TEMPORARY"='N' AND "OBJECT_ID"=58)


Statistics
----------------------------------------------------------
          0  recursive calls
          0  db block gets
          4  consistent gets
          0  physical reads
          0  redo size
...
...
          1  rows processed

While I have 2 Indexes on the same columns only the ordered changed, optimizer chose an Index on Object_ID and Temporary. As my sessions are interactive (and this sometimes mean that my sessions take more time than alloted :)), I asked the participants the reason behind this optimizer decision and there were lot many assumptions. Anju Garg came out with the correct guess. However, will disclose this later.

At this point, the question raised was, why there are 4 Consistent I/O’s? The assumption here was that it should be 3 (BLEVEL + LEAF BLOCK Access + Table Block).

Next, I dropped any one of the Index and re-created it as a Unique Index. Remember, Object_ID is 100% Distinct. So, I will drop and re-create T1_OT.

SQL> drop index t1_ot;

Index dropped.

Elapsed: 00:00:00.04
SQL> create unique index t1_ot_uq on t1(object_id, temporary);

Index created.

SQL> select index_name, blevel, leaf_blocks, clustering_factor, uniqueness from dba_indexes
where   table_name='T1'
order by 1;
  2    3
INDEX_NAME                         BLEVEL LEAF_BLOCKS CLUSTERING_FACTOR UNIQUENES
------------------------------ ---------- ----------- ----------------- ---------
T1_OT_UQ                                1         162              1457 UNIQUE
T1_TO                                   1         171              1493 NONUNIQUE

I will then execute the queries to check for the consistent gets. This time, the consistent gets for the execution plan with Unique Index is 3 (as against 4 for the same non-unique index).

select owner, object_name from t1
where      object_id = 58
and        temporary='N';

Execution Plan
----------------------------------------------------------
Plan hash value: 1959391432

----------------------------------------------------------------------------------------
| Id  | Operation                   | Name     | Rows  | Bytes | Cost (%CPU)| Time     |
----------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT            |          |     1 |    48 |     2   (0)| 00:00:01 |
|   1 |  TABLE ACCESS BY INDEX ROWID| T1       |     1 |    48 |     2   (0)| 00:00:01 |
|*  2 |   INDEX UNIQUE SCAN         | T1_OT_UQ |     1 |       |     1   (0)| 00:00:01 |
----------------------------------------------------------------------------------------

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

   2 - access("OBJECT_ID"=58 AND "TEMPORARY"='N')


Statistics
----------------------------------------------------------
          0  recursive calls
          0  db block gets
          3  consistent gets
          0  physical reads

There is a difference in the Consistent Gets with Unique and Non-Unique Index. The height of both these Indexes are exactly same. This difference was important to get to original question. So, I generated a 10046 trace for the 2 Queries (with Unique and Without Unique Scan) and the relevant portion from the trace is as under, which will explain the reason behind 4 Consistent Gets.

## 10046 portion for Non-Unique index. Please see the BOLD and UNDERLINED portion. The extra cr=1 for FETCH#18446604434610142176.
## In this case, once the Blocks are fetched from an Index (cr=2) and Table (cr=1) Total cr=3, there is an extra cr immediately after 
## SQL*Net message to client. So, the total cr = 2 + 1 + 1 (extra) = 4.

PARSE #18446604434610142176:c=118,e=119,p=0,cr=0,cu=0,mis=0,r=0,dep=0,og=1,plh=1259244381,tim=7093069466
EXEC #18446604434610142176:c=88,e=93,p=0,cr=0,cu=0,mis=0,r=0,dep=0,og=1,plh=1259244381,tim=7093070117
WAIT #18446604434610142176: nam='SQL*Net message to client' ela= 8 driver id=1413697536 #bytes=1 p3=0 obj#=0 tim=7093070421
WAIT #18446604434610142176: nam='db file scattered read' ela= 2292 file#=12 block#=275312 blocks=8 obj#=77545 tim=7093073241
WAIT #18446604434610142176: nam='db file sequential read' ela= 49 file#=12 block#=255875 blocks=1 obj#=77543 tim=7093073719
FETCH #18446604434610142176:c=2088,e=3043,p=9,cr=3,cu=0,mis=0,r=1,dep=0,og=1,plh=1259244381,tim=7093073891
WAIT #18446604434610142176: nam='SQL*Net message from client' ela= 624 driver id=1413697536 #bytes=1 p3=0 obj#=77543 tim=7093074878
FETCH #18446604434610142176:c=104,e=104,p=0,cr=1,cu=0,mis=0,r=0,dep=0,og=1,plh=1259244381,tim=7093075164
STAT #18446604434610142176 id=1 cnt=1 pid=0 pos=1 obj=77543 op='TABLE ACCESS BY INDEX ROWID T1 (cr=4 pr=9 pw=0 str=1 time=3109 us cost=2 size=48 card=1)'
STAT #18446604434610142176 id=2 cnt=1 pid=1 pos=1 obj=77545 op='INDEX RANGE SCAN T1_TO (cr=3 pr=8 pw=0 str=1 time=2835 us cost=1 size=0 card=1)'
WAIT #18446604434610142176: nam='SQL*Net message to client' ela= 6 driver id=1413697536 #bytes=1 p3=0 obj#=77543 tim=7093076331

## 10046 portion for Unique index. In this case, once the Blocks are fetched from an Index (cr=2) and Table (cr=1), there is no extra cr.

PARSE #18446604434610123376:c=134,e=135,p=0,cr=0,cu=0,mis=0,r=0,dep=0,og=1,plh=1959391432,tim=7120639467
EXEC #18446604434610123376:c=89,e=90,p=0,cr=0,cu=0,mis=0,r=0,dep=0,og=1,plh=1959391432,tim=7120640009
WAIT #18446604434610123376: nam='SQL*Net message to client' ela= 8 driver id=1413697536 #bytes=1 p3=0 obj#=0 tim=7120640248
WAIT #18446604434610123376: nam='db file scattered read' ela= 5875 file#=12 block#=260496 blocks=8 obj#=77546 tim=7120646397
WAIT #18446604434610123376: nam='db file sequential read' ela= 64 file#=12 block#=255875 blocks=1 obj#=77543 tim=7120646786
FETCH #18446604434610123376:c=1407,e=6569,p=9,cr=3,cu=0,mis=0,r=1,dep=0,og=1,plh=1959391432,tim=7120646947
STAT #18446604434610123376 id=1 cnt=1 pid=0 pos=1 obj=77543 op='TABLE ACCESS BY INDEX ROWID T1 (cr=3 pr=9 pw=0 str=1 time=6549 us cost=2 size=48 card=1)'
STAT #18446604434610123376 id=2 cnt=1 pid=1 pos=1 obj=77546 op='INDEX UNIQUE SCAN T1_OT_UQ (cr=2 pr=8 pw=0 str=1 time=6240 us cost=1 size=0 card=1)'
WAIT #18446604434610123376: nam='SQL*Net message from client' ela= 583 driver id=1413697536 #bytes=1 p3=0 obj#=77543 tim=7120652705
FETCH #18446604434610123376:c=15,e=15,p=0,cr=0,cu=0,mis=0,r=0,dep=0,og=0,plh=1959391432,tim=7120652925
WAIT #18446604434610123376: nam='SQL*Net message to client' ela= 5 driver id=1413697536 #bytes=1 p3=0 obj#=77543 tim=7120653074

From this, I can assume that the steps carried out for a Non-Unique Index is as under (as it an Index-Range Scan).

-	Read the Root Block to get the address of the Leaf Block (IO = 1). 
- 	Read the Leaf Block to check for the matching Object_ID and Temporary Column. Get the ROWID for the table block. (IO = 2).
-	Go to the Table Block to read the other required columns listed in the SELECT list. (IO=3).
-	Go back to the Index Block to check for any other Object_ID and Temporary Values. (IO=4).
-	It is here that it gets to know that there are no more rows.

Bullet Point 4 is not required for a Unique Scan as Oracle is aware that it is a Unique Index and therefore, there will be no additional read required. Further, to confirm this, I executed a query on OBJECT_ID using an Unique Index. Remember, while Object_Id is 100% Unique, but the Unique Index is on the 2 columns and I am not referring the 2nd column in the query, which will change the plan from UNIQUE SCAN to RANGE SCAN.

select owner, object_name from t1
where      object_id = 58;

Execution Plan
----------------------------------------------------------
Plan hash value: 1834913555

------------------------------------------------------------------------------------------------
| Id  | Operation                           | Name     | Rows  | Bytes | Cost (%CPU)| Time     |
------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT                    |          |     1 |    46 |     3   (0)| 00:00:01 |
|   1 |  TABLE ACCESS BY INDEX ROWID BATCHED| T1       |     1 |    46 |     3   (0)| 00:00:01 |
|*  2 |   INDEX RANGE SCAN                  | T1_OT_UQ |     1 |       |     2   (0)| 00:00:01 |
------------------------------------------------------------------------------------------------

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

   2 - access("OBJECT_ID"=58)

Statistics
----------------------------------------------------------
          0  recursive calls
          0  db block gets
          4  consistent gets 

So, this answers the question raised during the session on the rationale behind 4 Consistent Reads. Unique and Non-Unique Indexes are internally same with only a difference in the way these are accessed. With Index Range Scan, the behaviour of both the indexes are exactly same.

Now, for the another question on why the optimizer used T1_OT (by default) and not T1_TO ? The reason was a TIE between the 2 indexes, which is usually very rare with Cost Based Optimization and due to the TIE, optimizer preferred an Index in an alphabetical order. TI_OT comes before TI_TO. To demonstrate this, I dropped and recreated T1_TO as T1_1TO and optimized started using T1_1TO by default.