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How to Make Oracle Use the Correct Index

When the “wrong” index is used for a SQL query, it’s sometimes a struggle to coerce Oracle to use the correct index again.

There are many possible reasons for this, and I won’t try to discuss them all here.

The particulars for this case:

  • Wrong index chosen — execution time went from 0.01 seconds to 0.42 seconds.
  • This has a very bad effect on performance when this SQL is called thousands of times.
  • One of the predicates in the WHERE clause uses a PL/SQL function.
  • This is a third-party application — we could not make changes to SQL.

Looking for a quick win, we first ran a tuning task report.

Oracle recommended creating a baseline, so we tried that.

In this case however, attempting to create the baseline resulted in an error: ORA-13846:

SQL# host  oerr ora 13846
13846, 00000, "Cannot create SQL plan baseline on the given plan"
// *Cause: There are either multiple plans exist for the given value or the
//         plan is not reproducible.
// *Action: Call Oracle Support.

A search of this error on My Oracle Support (MOS) revealed … nothing. There were no results returned from MOS when searching for ORA-13846.

A Google search for that error did bring back a number of results, but none of them appeared to be applicable, or at least we found no recommended actions that we could take.

A couple of things led us to believe this was likely to be a bug:

  • “Action: Call Oracle Support”
  • This was Oracle 12.1.0.2, and unpatched

Could this problem have been fixed by updating statistics on the affected tables and indexes?

That’s possible, and I believe quite likely.

However, there were several things beyond our control that day, and we had to work within our means.

One thing was certain; when a particular query was run, we knew which index it should always use.

The solution we came up with was: use dbms_sqldiag_internal.i_create_sql_patch. This is a package that allows us to specify a hint that should be used for a particular SQL statement.

When we did this, new executions of the SQL statement began using the correct index, and performance was restored.

For Oracle 12.2 and later, the procedure to use is: dbms_sqldiag.create_sql_patch.

One of the following demonstrations is a recreation of the issue we encountered that day with some similar test data.

After showing the problem, I’ll show how you can remediate it with a SQL Patch. But, that’s not all. I’ll also provide two other demonstrations, both of which are things we couldn’t implement that day, but are actually more effective.

While the production database was 12.1.0.2, the following demonstrations are being done on Oracle 19.8.0.

Let’s get on with the demos.

Building the Test Data

The hardest part of creating a reproducible test case is often just creating a data set to replicate the problem.

While the data created here is used to show the issue, I wasn’t able to get the data to reproduce the issue without “cheating” a bit, as you shall see.

First, create the table func_test.

create table func_test (
   comp_id number,
   comp_name varchar2(20),
   pay_id number,
   credit_id number,
   period_end_date date,
   trans_type varchar2(1),
   status varchar2(10),
   rval number,
   c1 varchar2(20),
   c2 varchar2(20),
   c3 varchar2(20)
);

The next step is to create some test data.

This SQL will create 2.5M rows.

insert into func_test
with companies as (
   select
      level company_id,
      dbms_random.string('L', 10) company_name
   from dual
   connect by level <= 100
),
payids as (
   select level pay_id
   from dual
   connect by level <= 5000
),
credit_ids as (
   select level credit_id
   from dual
   connect by level <= 5
)
select
   c.company_id
   , c.company_name
   , p.pay_id
   , ci.credit_id
   ,case trunc(dbms_random.value(1,5))
      when 1 then to_date('2020-03-31','yyyy-mm-dd')
      when 2 then to_date('2020-06-30','yyyy-mm-dd')
      when 3 then to_date('2020-09-30','yyyy-mm-dd')
      when 4 then to_date('2020-12-31','yyyy-mm-dd')
   end period_end_date
   , substr('ABCD',trunc(dbms_random.value(1,5)),1) trans_type
   , decode(mod(rownum,3),0,'ACTIVE',1,'INACTIVE',2,'PENDING') status
   , trunc(dbms_random.value(1,1000)) rval
   , dbms_random.string('L', 20) c1
   , dbms_random.string('L', 20) c2
   , dbms_random.string('L', 20) c3
from companies c
   ,payids p
   , credit_ids ci;

Once the data is created, the indexes are added:

create index  comp_id_idx on func_test(comp_id, pay_id);
create index  bad_idx on func_test(rval, period_end_date);

And now for the part where I cheat — I manipulate the index statistics so the Oracle optimizer will favor the “bad” index.

begin

   dbms_stats.gather_table_stats(ownname => user, tabname => 'FUNC_TEST');
   dbms_stats.delete_index_stats(user,'BAD_IDX');
   dbms_stats.delete_index_stats(user,'COMP_ID_IDX');

   dbms_stats.set_index_stats(
      ownname => user, 
      indname => 'BAD_IDX', 
      no_invalidate => FALSE,
      indlevel => 2,
      numlblks => 8,
      numrows => 100,
      numdist => 100,
      clstfct => 8
   );

   dbms_stats.set_index_stats(
      ownname => user, 
      indname => 'COMP_ID_IDX', 
      no_invalidate => FALSE,
      indlevel => 5,
      numlblks => 32000,
      numrows => 10e6,
      numdist => 1e6,
      clstfct => 1e6
   );

end;
/

Here’s how the table and index statistics look:

SQL# @show-stats

OBJECT_NAME                    OBJEC LAST_ANALYZED           BLOCKS   NUM_ROWS
------------------------------ ----- ------------------- ---------- ----------
FUNC_TEST                      TABLE 2021-01-15 10:34:12      38657    2500000
BAD_IDX                        INDEX 2021-01-15 10:34:36          8        100
COMP_ID_IDX                    INDEX 2021-01-15 10:34:36      32000   10000000

3 rows selected.

You can see where the optimizer is being lied to.

The COMP_ID_IDX index is made to look more expensive than it really is by setting blocks to 32000, and the number of rows to 10M.

Conversely, the BAD_IDX index has been made to appear the right choice, as it has been made to appear as having only eight blocks and 100 rows.

The Test Query

Here’s the test query that will be used.

-- dbms_xplan will not work properly when serveroutput is enabled
set serveroutput off

var period_end_date varchar2(10)
var comp_id number
var pay_id number

-- set bind variables for where clause
begin
   :period_end_date := '2020-06-30';
   :comp_id := 42;
   :pay_id := 37;
end;
/

select count(*)
from (
select
/*+ gather_plan_statistics */
   rval, is_prime(rval) rprime
from func_test ft
where ft.comp_id = :comp_id
   and ft.period_end_date = to_date(:period_end_date,'yyyy-mm-dd')
   and ft.trans_type = 'B'
   and ft.status = 'ACTIVE'
   and is_prime(rval) = 'Y'
)
/

You may be wondering about is_prime(rval), which is found in both the projection (columns selected) and as a predicate (WHERE clause).

The RVAL column was created with a random integer in the range 1-999.

The is_prime() function is called to determine if value is prime. The purpose is to simulate what was seen in a real application.

Though the is_prime() code is a rather brute force prime detector, the largest integer evaluated will be 999, so it doesn’t take long to run.

create or replace function is_prime ( prime_test_in integer ) 
return varchar2 deterministic
   is
      i integer;
      is_a_prime_number boolean;
      prime_number integer;
   begin
      
      /* obviously prime */
      if prime_test_in = 2
         or prime_test_in = 3
         or prime_test_in = 5
         or prime_test_in = 7
      then
         return 'Y';
      elsif prime_test_in = 1
      then
         return 'N';
      elsif mod(prime_test_in,2) = 0
      then
         return 'N';
      elsif mod(prime_test_in,3) = 0
      then
         return 'N';
      elsif mod(prime_test_in,5) = 0
      then
         return 'N';
      elsif mod(prime_test_in,7) = 0
      then
         return 'N';
      end if;

      /* brute force prime detection */
      i := 11;
      loop
         i := i + 2;

         if i > prime_test_in / 2 then
            exit;
         end if;

         if mod(prime_test_in,i) = 0 then
            return 'N';
         end if;
      end loop;
      
      return 'Y' ;
   end;

Evaluating all primes in the 1-999 range takes 10 milliseconds:

SQL# l
  1  declare
  2     v_is_prime varchar2(1);
  3  begin
  4     for i in 1..999
  5     loop
  6             v_is_prime := is_prime(i);
  7     end loop;
  8* end;
SQL# /

PL/SQL procedure successfully completed.

Elapsed: 00:00:00.01

The First Test

Now we can run the SQL and see what we’re up against.

Note: Both the shared pool and buffer cache are flushed between tests. Please DO NOT do this in a production database.

The showplan_last.sql script is used to run dbms_xplan.display_cursor for the most recently run SQL in a SQLPlus session.

SQL# @@flush
System altered.
System altered.

SQL# @@q1

COUNT(*)
----------
83
1 row selected.

Elapsed: 00:00:13.16

At 13.16 seconds, this is not exactly a speedy query. The users are expecting something in the order of 0.5 seconds.

We can look at the execution plan to see why that is:

SQL# @@showplan_last

PLAN_TABLE_OUTPUT
-----------------
SQL_ID  00v5ashkdhw9n, child number 0
-------------------------------------
select count(*) from ( select /*+ gather_plan_statistics */    rval,
is_prime(rval) rprime from func_test ft where ft.comp_id = :comp_id
and ft.period_end_date = to_date(:period_end_date,'yyyy-mm-dd')    and
ft.trans_type = 'B'    and ft.status = 'ACTIVE'    and is_prime(rval) =
'Y' )

Plan hash value: 2716387093

-----------------------------------------------------------------------------------------------------------------------------------------------------
| Id  | Operation                            | Name      | Starts | E-Rows |E-Bytes| Cost (%CPU)| E-Time   | A-Rows |   A-Time   | Buffers | Reads  |
-----------------------------------------------------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT                     |           |      1 |        |       |    18 (100)|          |      1 |00:00:13.08 |     109K|  40210 |
|   1 |  SORT AGGREGATE                      |           |      1 |      1 |    26 |            |          |      1 |00:00:13.08 |     109K|  40210 |
|*  2 |   TABLE ACCESS BY INDEX ROWID BATCHED| FUNC_TEST |      1 |      5 |   130 |    18   (0)| 00:00:01 |     83 |00:00:00.41 |     109K|  40210 |
|*  3 |    INDEX SKIP SCAN                   | BAD_IDX   |      1 |    100 |       |    10   (0)| 00:00:01 |    105K|00:00:06.09 |    4491 |   4035 |
-----------------------------------------------------------------------------------------------------------------------------------------------------

Query Block Name / Object Alias (identified by operation id):
-------------------------------------------------------------

1 - SEL$F5BB74E1
2 - SEL$F5BB74E1 / FT@SEL$2
3 - SEL$F5BB74E1 / FT@SEL$2

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

2 - filter(("FT"."COMP_ID"=:COMP_ID AND "FT"."TRANS_TYPE"='B' AND "FT"."STATUS"='ACTIVE'))
3 - access("FT"."PERIOD_END_DATE"=TO_DATE(:PERIOD_END_DATE,'yyyy-mm-dd'))
filter(("FT"."PERIOD_END_DATE"=TO_DATE(:PERIOD_END_DATE,'yyyy-mm-dd') AND "IS_PRIME"("RVAL")='Y'))

Column Projection Information (identified by operation id):
-----------------------------------------------------------

1 - (#keys=0) COUNT(*)[22]
3 - "FT".ROWID[ROWID,10]

39 rows selected.

To begin with, look at the number of estimated rows (E-Rows) in the plan: 100. This is evidence of the made-up statistics where we tell Oracle that this index is on 100 rows.

The actual number of rows (A-Rows) is 105,000. And for each of those rows, the is_prime() function was called.

How do we know the function was called that many times? After all, that doesn’t show up in a 10046 trace.

One way is to remove the use of the function, and rerun the query:

@@flush
System altered.
System altered.
Session altered.

  1  select count(*)
  2  from (
  3  select /*+ gather_plan_statistics */
  4     rval -- , is_prime(rval) rprime
  5  from func_test ft
  6  where ft.comp_id = :comp_id
  7     and ft.period_end_date = to_date(:period_end_date,'yyyy-mm-dd')
  8     and ft.trans_type = 'B'
  9     and ft.status = 'ACTIVE'
 10     --and is_prime(rval) = 'Y'
 11* )
SQL# /

  COUNT(*)
----------
       508

1 row selected.

Elapsed: 00:00:08.90

That was significantly quicker than before — 8.9 seconds vs 13.16 seconds.

SQL# @showplan_last

PLAN_TABLE_OUTPUT
---------------------
SQL_ID  d6tz6hqp3yutw, child number 0
-------------------------------------
select count(*) from ( select /*+ gather_plan_statistics */    rval --
, is_prime(rval) rprime from func_test ft where ft.comp_id = :comp_id
and ft.period_end_date = to_date(:period_end_date,'yyyy-mm-dd')    and
ft.trans_type = 'B'    and ft.status = 'ACTIVE'    --and is_prime(rval)
= 'Y' )

Plan hash value: 2716387093

-----------------------------------------------------------------------------------------------------------------------------------------------------
| Id  | Operation                            | Name      | Starts | E-Rows |E-Bytes| Cost (%CPU)| E-Time   | A-Rows |   A-Time   | Buffers | Reads  |
-----------------------------------------------------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT                     |           |      1 |        |       |    18 (100)|          |      1 |00:00:01.46 |     625K|   2276 |
|   1 |  SORT AGGREGATE                      |           |      1 |      1 |    22 |            |          |      1 |00:00:01.46 |     625K|   2276 |
|*  2 |   TABLE ACCESS BY INDEX ROWID BATCHED| FUNC_TEST |      1 |    521 | 11462 |    18   (0)| 00:00:01 |    508 |00:00:03.21 |     625K|   2276 |
|*  3 |    INDEX SKIP SCAN                   | BAD_IDX   |      1 |    100 |       |    10   (0)| 00:00:01 |    625K|00:00:00.27 |    4009 |      0 |
-----------------------------------------------------------------------------------------------------------------------------------------------------

Query Block Name / Object Alias (identified by operation id):
-------------------------------------------------------------

1 - SEL$F5BB74E1
2 - SEL$F5BB74E1 / FT@SEL$2
3 - SEL$F5BB74E1 / FT@SEL$2

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

2 - filter(("FT"."COMP_ID"=:COMP_ID AND "FT"."TRANS_TYPE"='B' AND "FT"."STATUS"='ACTIVE'))
3 - access("FT"."PERIOD_END_DATE"=TO_DATE(:PERIOD_END_DATE,'yyyy-mm-dd'))
filter("FT"."PERIOD_END_DATE"=TO_DATE(:PERIOD_END_DATE,'yyyy-mm-dd'))

Column Projection Information (identified by operation id):
-----------------------------------------------------------

1 - (#keys=0) COUNT(*)[22]
3 - "FT".ROWID[ROWID,10]

The A-Rows increased dramatically, when the predicate is_prime(rval) was removed. Even so, the query now completes 4.26 seconds quicker, as the overhead of calling the function has been removed.

Most of this issue is due to the choice of index made by the optimizer.

While the query returns only 83 rows, 105k rows were scanned in the index to narrow down that choice

The column list for BAD_IDX is (rval,trans_type).

The column list for the COMP_ID_IDX index is (comp_id, pay_id).

Since the first predicate for the query is on comp_id, and there are 100 distinct comp_id values, we would expect that index to be a better choice.

As you may recall, at this time we couldn’t do anything with optimizer statistics. Since this is a third-party app, we couldn’t alter the SQL, nor could we create an index. While creating an index might be a good choice if we had sufficient time for testing, this was an emergency fix situation, so we had to take another approach.

Hinting the SQL

The next we can do is hint the SQL to tell the optimizer we want to use a different index.

You may be wondering why the hint wasn’t placed in the part of the query where it it will be used, like this:

4  select /*+ gather_plan_statistics index(ft comp_id_idx)*/
5     rval, is_prime(rval) rprime
6  from func_test ft

As it is, the hint requires us to specify the query block, which is a bit of extra trouble.

I’ll explain this a little later.

SQL# @flush
System altered.
System altered.
Session altered.

SQL# get afiedt.buf
  1  select /*+ index(@"SEL$2" "FT" "COMP_ID_IDX") */
  2     count(*)
  3  from (
  4  select /*+ gather_plan_statistics */
  5     rval, is_prime(rval) rprime
  6  from func_test ft
  7  where ft.comp_id = :comp_id
  8     and ft.period_end_date = to_date(:period_end_date,'yyyy-mm-dd')
  9     and ft.trans_type = 'B'
 10     and ft.status = 'ACTIVE'
 11     and is_prime(rval) = 'Y'
 12* )
SQL# /

  COUNT(*)
----------
        83

1 row selected.

Elapsed: 00:00:00.47

That’s quite a substantial improvement. From 13 seconds to 0.47 seconds.

And here’s why:

-------------------------------------------------------------------------------------------------------------------------------------------------------
| Id  | Operation                            | Name        | Starts | E-Rows |E-Bytes| Cost (%CPU)| E-Time   | A-Rows |   A-Time   | Buffers | Reads  |
-------------------------------------------------------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT                     |             |      1 |        |       | 10331 (100)|          |      1 |00:00:00.24 |     960 |    479 |
|   1 |  SORT AGGREGATE                      |             |      1 |      1 |    26 |            |          |      1 |00:00:00.24 |     960 |    479 |
|*  2 |   TABLE ACCESS BY INDEX ROWID BATCHED| FUNC_TEST   |      1 |      5 |   130 | 10331   (1)| 00:00:01 |     83 |00:00:00.21 |     960 |    479 |
|*  3 |    INDEX RANGE SCAN                  | COMP_ID_IDX |      1 |    100K|       |   326   (1)| 00:00:01 |  25000 |00:00:00.09 |      66 |     66 |
-------------------------------------------------------------------------------------------------------------------------------------------------------

The A-Rows value has been reduced from 105k to 25k.

But more importantly, the is_prime(rval) function is no longer being called for every evaluated row.

Just how important is that? Let’s perform a test to find out.

Earlier you saw a test where is_prime() evalated all digits in the range of 1..999 for prime.

That ran in 0.01 seconds.

Let’s run a similar test, but now run it 105k times.

declare
   v_is_prime varchar2(1);
begin
   for j in 1..105
   loop
      for i in 1..999
      loop
         v_is_prime := is_prime(i);
      end loop;
   end loop;
end;

SQL# /

Elapsed: 00:00:00.74

As you can see, it’s still quite fast.

But, let’s change it to more closely simulate what’s occurring with the SQL statement.

This time, rather than a direct assignment, the value will be assigned via select X into Y from dual.

declare
   v_is_prime varchar2(1);
begin
   for j in 1..105
   loop
      for i in 1..999
      loop
         select is_prime(i) into v_is_prime from dual;
      end loop;
   end loop;
end;

SQL# /

Elapsed: 00:00:04.92

Now the time required is very close to the time required to scan the BAD_IDX index when the query took 13 seconds. Scanning the index accounted for six seconds of the query time.

When we removed the parts of the SQL that called the is_prime(rval) function, the index scan time only took 0.27 seconds. Calling the is_prime(rval) function accounted for the rest of the time.

As shown in the tests, when switching from direct assignment to the variable v_is_prime, to assignment by select from dual, the decrease in performance was 7x.

The same thing happens in the test query.

The context switch between SQL and PL/SQL (calling the function) is very expensive.

SQL Patch

Now we know why the query is so slow.

While the developer in me thinks that using a function in a WHERE clause is pretty cool, my DBA and performance analyst side thinks it looks like a serious potential performance issue (it is).

Nonetheless, this is what we have to work with.

At this point we decided to use dbms_sqldiag_internal.i_create_sql_patch, so we could provide a hint to the optimizer; telling it to use our preferred index.

What follows is a simplified version of the script, which brings us to the hint with the query block included.

It’s necessary to tell create_sql_patch which part of the query the hint applies to. This is because when the query is nested, as our test query is, the create_sql_patch code applies the hint to the outermost query. If we want the patch to be applied to the correct part of the query, we have to specify that in the hint.

The following is a partial reproduction of the execution plan as it was first seen earlier.

Recall the the table is aliased as “ft” in the SQL: “from func_test ft.”

In the query block section of the execution plan we see that line 3 in the operations (INDEX SKIP SCAN) corresponds to the query block name “SEL$F5BB74E1.”

In the parsed query, the table is referred to as “FT@SEL$2.”

-----------------------------------------------------------------------------------------------------------------------------------------------------
| Id  | Operation                            | Name      | Starts | E-Rows |E-Bytes| Cost (%CPU)| E-Time   | A-Rows |   A-Time   | Buffers | Reads  |
-----------------------------------------------------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT                     |           |      1 |        |       |    18 (100)|          |      1 |00:00:13.08 |     109K|  40210 |
|   1 |  SORT AGGREGATE                      |           |      1 |      1 |    26 |            |          |      1 |00:00:13.08 |     109K|  40210 |
|*  2 |   TABLE ACCESS BY INDEX ROWID BATCHED| FUNC_TEST |      1 |      5 |   130 |    18   (0)| 00:00:01 |     83 |00:00:00.41 |     109K|  40210 |
|*  3 |    INDEX SKIP SCAN                   | BAD_IDX   |      1 |    100 |       |    10   (0)| 00:00:01 |    105K|00:00:06.09 |    4491 |   4035 |
-----------------------------------------------------------------------------------------------------------------------------------------------------

Query Block Name / Object Alias (identified by operation id):
-------------------------------------------------------------

   1 - SEL$F5BB74E1
   2 - SEL$F5BB74E1 / FT@SEL$2
   3 - SEL$F5BB74E1 / FT@SEL$2

Various sources recommend using the query block name as part of the hint; others recommend using the object name.

As a reminder, here’s the test query again:

select    -- outer query 
   count(*)
from (   -- inner query
   select /*+ gather_plan_statistics */
      rval, is_prime(rval) rprime
   from func_test ft, dual d
   where ft.comp_id = :comp_id
      and ft.period_end_date = to_date(:period_end_date,'yyyy-mm-dd')
      and ft.trans_type = 'B'
      and ft.status = 'ACTIVE'
      and is_prime(rval) = 'Y'
)

When specifying no hint, the wrong index was used, as expected.

When adding a hint to the outer query in this manner: select /*+ index("FT" "COMP_ID_IDX") */, the wrong index was still used.

The hint would be useless when applied to the outer query; the index to be used affects the inner query only.

When adding the hint with either the query block name, or the object alias, or even just the second part of the object alias, the correct index would be used. Specifying the QBN and the alias together also worked.

Hinted with:

  • query block name: select /*+ index(@"SEL$F5BB74E1" "FT" "COMP_ID_IDX") */
  • alias name: select /*+ index("FT"@"SEL$2" "FT" "COMP_ID_IDX") */
  • partial alias name: select /*+ index(@"SEL$2" "FT" "COMP_ID_IDX") */
  • QBN and the object alias: select /*+ index(@"SEL$F5BB74E1" "FT"@"SEL$2" "FT" "COMP_ID_IDX") */

If one character was changed in either the QBN or the object alias, then the hint would be ignored. This was just to prove that both were having an effect.

Following this testing, the SQL was hinted this way: select /*+ index(@"SEL$2" "FT" "COMP_ID_IDX") */

Next, a script was prepared to create the SQL patch.

The real script that was used to create the SQL patch checks for patch existence and possibly other niceties, but for the purposes of this article, I’m keeping it brief.

SYS@pdb1 AS SYSDBA>
declare
   v_sql_id varchar2(13);
   v_patch_name varchar2(2000);
begin
   v_sql_id := :b_sql_id;
   -- if prior to 12.2
   -- dbms_sqldiag_internal.i_create_sql_patch
   v_patch_name :=  dbms_sqldiag.create_sql_patch(
      sql_id  => v_sql_id,
      hint_text => 'index(@"SEL$2" "FT" "COMP_ID_IDX")',
      --hint_text => 'gather_plan_statistics',
      name      => 'ft_' || v_sql_id
   );
   dbms_output.put_line('patch name: ' || v_patch_name);
end;
 16  /
patch name: ft_00v5ashkdhw9n

PL/SQL procedure successfully completed.

Did it work? Yes, it did.

SQL# get afiedt.buf
  1  select count(*)
  2  from (
  3  select /*+ gather_plan_statistics */
  4     rval, is_prime(rval) rprime
  5  from func_test ft
  6  where ft.comp_id = :comp_id
  7     and ft.period_end_date = to_date(:period_end_date,'yyyy-mm-dd')
  8     and ft.trans_type = 'B'
  9     and ft.status = 'ACTIVE'
 10     and is_prime(rval) = 'Y'
 11* )
SQL# /

  COUNT(*)
----------
        83

1 row selected.

Elapsed: 00:00:00.49

The time of 0.49 is quite an improvement on 13 seconds.

The execution plan shows us why it’s now so fast:

SQL# @showplan_last

Plan hash value: 1388359396

-------------------------------------------------------------------------------------------------------------------------------------------------------
| Id  | Operation                            | Name        | Starts | E-Rows |E-Bytes| Cost (%CPU)| E-Time   | A-Rows |   A-Time   | Buffers | Reads  |
-------------------------------------------------------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT                     |             |      1 |        |       | 10331 (100)|          |      1 |00:00:00.24 |     960 |    478 |
|   1 |  SORT AGGREGATE                      |             |      1 |      1 |    26 |            |          |      1 |00:00:00.24 |     960 |    478 |
|*  2 |   TABLE ACCESS BY INDEX ROWID BATCHED| FUNC_TEST   |      1 |      5 |   130 | 10331   (1)| 00:00:01 |     83 |00:00:00.21 |     960 |    478 |
|*  3 |    INDEX RANGE SCAN                  | COMP_ID_IDX |      1 |    100K|       |   326   (1)| 00:00:01 |  25000 |00:00:00.08 |      66 |     66 |
-------------------------------------------------------------------------------------------------------------------------------------------------------

Total hints for statement: 1
---------------------------------------------------------------------------

   1 -  SEL$F5BB74E1
           -  index(@"SEL$2" "FT" "COMP_ID_IDX")

Note
-----
   - SQL patch "ft_00v5ashkdhw9n" used for this statement

It shows that SQL Path “ft_00v5ashkdhw9n” was successfully used to provide a hint to use the index COMP_ID_IDX.

While this did fix the issue in this database, it’s not the end of the story.

Alternatives

There are at least two alternatives that may be used to deal with this.

1) Function-based index

Though in the above instance we couldn’t create an index, it could be a consideration for the future, when proper testing can be done.

Oracle has the ability to create indexes based on a function.

The advantages to using this FBI (function-based index) are:

  • the values for is_prime(rval) are pre-computed in the index.
  • the index can then be used for the table row lookup.

Here is our index DDL:

create index func_test_fbi_idx on func_test(comp_id,pay_id, is_prime(rval))

The database statistics will be re-gathered (without lying to the optimizer), the index built, and the test query re-run.

  1  begin
  2     dbms_stats.delete_table_stats(ownname => user, tabname => 'FUNC_TEST', cascade_indexes => true);
  3     dbms_stats.gather_table_stats(ownname => user, tabname => 'FUNC_TEST');
  4     dbms_stats.gather_index_stats(user,'BAD_IDX');
  5     dbms_stats.gather_index_stats(user,'COMP_ID_IDX');
  6* end;
  7  /

Elapsed: 00:00:09.51

SQL# create index func_test_fbi_idx on func_test(comp_id,pay_id, is_prime(rval));

Index created.

Elapsed: 00:00:46.54

SQL# @show-stats

OBJECT_NAME                    OBJEC LAST_ANALYZED           BLOCKS   NUM_ROWS
------------------------------ ----- ------------------- ---------- ----------
FUNC_TEST                      TABLE 2021-01-15 13:49:06      38657    2500000
BAD_IDX                        INDEX 2021-01-15 13:49:14       8306    2500000
COMP_ID_IDX                    INDEX 2021-01-15 13:49:15       6336    2500000
FUNC_TEST_FBI_IDX              INDEX 2021-01-15 13:51:07       6958    2500000

Drop the SQL Patch:

SQL# exec dbms_sqldiag.drop_sql_patch(name => 'ft_00v5ashkdhw9n' )

PL/SQL procedure successfully completed.

Now, rerun the test query.

SQL# @@flush
System altered.
System altered.
Session altered.

SQL# l
  1  select count(*)
  2  from (
  3  select /*+ gather_plan_statistics */
  4     rval, is_prime(rval) rprime
  5  from func_test ft
  6  where ft.comp_id = :comp_id
  7     and ft.period_end_date = to_date(:period_end_date,'yyyy-mm-dd')
  8     and ft.trans_type = 'B'
  9     and ft.status = 'ACTIVE'
 10     and is_prime(rval) = 'Y'
 11* )

#SQL /

  COUNT(*)
----------
        83

1 row selected.

Elapsed: 00:00:00.34

This is the fastest execution yet. Let’s take a look at the execution plan:

SQL# @showplan_last

Plan hash value: 2498653831

-------------------------------------------------------------------------------------------------------------------------------------------------------------
| Id  | Operation                            | Name              | Starts | E-Rows |E-Bytes| Cost (%CPU)| E-Time   | A-Rows |   A-Time   | Buffers | Reads  |
-------------------------------------------------------------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT                     |                   |      1 |        |       |    75 (100)|          |      1 |00:00:00.25 |     462 |    458 |
|   1 |  SORT AGGREGATE                      |                   |      1 |      1 |   106 |            |          |      1 |00:00:00.25 |     462 |    458 |
|*  2 |   TABLE ACCESS BY INDEX ROWID BATCHED| FUNC_TEST         |      1 |      5 |   530 |    75   (0)| 00:00:01 |     83 |00:00:00.10 |     462 |    458 |
|*  3 |    INDEX RANGE SCAN                  | FUNC_TEST_FBI_IDX |      1 |    100 |       |    72   (0)| 00:00:01 |   4220 |00:00:00.01 |      73 |     73 |
-------------------------------------------------------------------------------------------------------------------------------------------------------------

Query Block Name / Object Alias (identified by operation id):
-------------------------------------------------------------

   1 - SEL$F5BB74E1
   2 - SEL$F5BB74E1 / FT@SEL$2
   3 - SEL$F5BB74E1 / FT@SEL$2

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

   2 - filter(("FT"."TRANS_TYPE"='B' AND "FT"."STATUS"='ACTIVE' AND "FT"."PERIOD_END_DATE"=TO_DATE(:PERIOD_END_DATE,'yyyy-mm-dd')))
   3 - access("FT"."COMP_ID"=:COMP_ID AND "FT"."SYS_NC00012$"='Y')
       filter("FT"."SYS_NC00012$"='Y')

Column Projection Information (identified by operation id):
-----------------------------------------------------------

   1 - (#keys=0) COUNT(*)[22]
   3 - "FT".ROWID[ROWID,10], "FT"."SYS_NC00012$"[VARCHAR2,4000]

The number of A-Rows scanned has been greatly reduced, from 25000 down to 4220.

In addition, you may have noticed the filter FT”.”SYS_NC00012$”=’Y’. What’s that?

Creating a function-based index has caused Oracle to create an invisible column in the test table:

SQL# col column_name format a20
SQL# l
  1  select
  2     column_id
  3     , column_name
  4     , nullable
  5     , hidden_column
  6  from user_tab_cols
  7  where table_name = 'FUNC_TEST'
  8* order by column_id
SQL# /

 COLUMN_ID COLUMN_NAME          N HID
---------- -------------------- - ---
         1 COMP_ID              Y NO
         2 COMP_NAME            Y NO
         3 PAY_ID               Y NO
         4 CREDIT_ID            Y NO
         5 PERIOD_END_DATE      Y NO
         6 TRANS_TYPE           Y NO
         7 STATUS               Y NO
         8 RVAL                 Y NO
         9 C1                   Y NO
        10 C2                   Y NO
        11 C3                   Y NO
           SYS_NC00012$         Y YES

12 rows selected.

As the saying goes, there is no free lunch. That precomputed value had to be stored, and Oracle has stored it in hidden column SYS_NC00012$.

  1* select SYS_NC00012$ from func_test where rownum < 11
SQL# /

SYS_NC00012$
-------------
N
N
N
N
N
N
N
N
N
Y

10 rows selected.

The reduction in CPU usage may well make this a worthwhile tradeoff; that is, trading a little space for a significant performance increase.

2) Design changes

As this is a third-party app, we can’t make any design decisions.

If you’re in a position to suggest design changes, however, you may want to consider this section as well.

In general, using functions within a SQL statement isn’t optimal for database performance.

What if, rather than using a function, you used a lookup table instead?

I can hear the groans now: “Adding a join? Joins are slow!”

The truth is, joins aren’t slow. If there’s one thing Oracle does well, it’s joining tables.

However, it’s very easy to design tables and SQL statements in such a way that joins are very slow.

In reality it’s not that joins are slow, it’s simply that the design of the tables, indexes and SQL can lead to performance issues caused when far too many rows are being considered. But, that’s not the point of this article …

Let’s create a table, PRIMES, that consists of all primes found in the range of 1..999.

create table primes
   prime_number integer not null,
   constraint pk_prime primary key (prime_number)
) organization index;

I’m not explaining the code to populate this here, as it would require a rather lengthy side-tracking from the main topic.

We now have the first 168 primes:

-- gather stats
#SQL exec dbms_stats.gather_table_stats(ownname => user, tabname => 'PRIMES')

#SQL @@show-stats

OBJECT_NAME                    OBJEC LAST_ANALYZED           BLOCKS   NUM_ROWS
------------------------------ ----- ------------------- ---------- ----------
FUNC_TEST                      TABLE 2021-01-15 13:49:06      38657    2500000
BAD_IDX                        INDEX 2021-01-15 13:49:14       8306    2500000
COMP_ID_IDX                    INDEX 2021-01-15 13:49:15       6336    2500000
PK_PRIME                       INDEX 2021-01-15 14:37:51          1        168

4 rows selected.

Now that we have the primes, we can drop the function-based index, and rewrite the query to avoid the use of the is_prime(rval) function in the predicate.

SQL# @flush
System altered.
System altered.
Session altered.

SQL# drop index func_test_fbi_idx;
Index dropped.

SQL# get afiedt.buf
  1  select count(*)
  2  from (
  3  select /*+ gather_plan_statistics */
  4     rval, 'Y' rprime
  5  from func_test ft
  6  join primes pf on pf.prime_number = ft.rval
  7  where ft.comp_id = :comp_id
  8     and ft.period_end_date = to_date(:period_end_date,'yyyy-mm-dd')
  9     and ft.trans_type = 'B'
 10     and ft.status = 'ACTIVE'
 11     --and is_prime(rval) = 'Y'
 12* )
SQL# /

  COUNT(*)
----------
        83

1 row selected.

Elapsed: 00:00:00.25

This execution time is the fastest yet.

What’s especially nice is there’s no chance of that function being used in the predicate.

Notice that there’s no need to use the is_prime(rval) in the column projection either, as the only rows returned are those where rval is prime.

SQL# @showplan_last

Plan hash value: 3520673696

--------------------------------------------------------------------------------------------------------------------------------------------------------
| Id  | Operation                             | Name        | Starts | E-Rows |E-Bytes| Cost (%CPU)| E-Time   | A-Rows |   A-Time   | Buffers | Reads  |
--------------------------------------------------------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT                      |             |      1 |        |       |   505 (100)|          |      1 |00:00:00.19 |     482 |    453 |
|   1 |  SORT AGGREGATE                       |             |      1 |      1 |    30 |            |          |      1 |00:00:00.19 |     482 |    453 |
|   2 |   NESTED LOOPS                        |             |      1 |    215 |  6450 |   505   (1)| 00:00:01 |     83 |00:00:00.17 |     482 |    453 |
|*  3 |    TABLE ACCESS BY INDEX ROWID BATCHED| FUNC_TEST   |      1 |    521 | 13546 |   505   (1)| 00:00:01 |    508 |00:00:00.11 |     478 |    452 |
|*  4 |     INDEX RANGE SCAN                  | COMP_ID_IDX |      1 |  25000 |       |    66   (0)| 00:00:01 |  25000 |00:00:00.07 |      66 |     66 |
|*  5 |    INDEX UNIQUE SCAN                  | PK_PRIME    |    508 |      1 |     4 |     0   (0)|          |     83 |00:00:00.01 |       4 |      1 |
--------------------------------------------------------------------------------------------------------------------------------------------------------

This query execution plan is slightly more complex than the others, but with an execution time of 0.25 seconds, it’s clearly the fastest.

When it comes to performance issues, sometimes the most expedient choice is not the one you might prefer. It’s necessary to balance out the remediation with the current goals. In this case the current goal was “make the system usable so our users can do their jobs,” making the use of a SQL Patch the best choice on this day.

Prologue

Full disclosure — I did cheat a little in this article.

While the situation shown is relatively close to what was really seen, and the method used was identical, there was a slight difference in the real production table. The column being passed to the function was not a simple integer, it was a nested table.

If you’re wondering how to deal with that, here’s a hint; the options will be more limited when a nested array is used.

Look for more information on that in a follow up article.

Code

All code for this article may be found at https://github.com/jkstill/oracle-demos/tree/master/function-based-index_vs_table-lookup.

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