Parse Time

Dominic Brooks published a note recently about some very nasty SQL – originally thinking that it was displaying a run-time problem due to the extreme number of copies of the lnnvl() function the optimizer had produced. In fact it turned out to be a parse-time problem rather than a run-time problem, but when I first read Dominic’s note I was sufficiently surprised that I decided to try modelling the query.

Unfortunately the query had more than 1,000 predicates, (OR’ed together) and some of them included in-lists.  Clearly, writing this up by hand wasn’t going to be a good idea, so I wrote a script to generate both the data, and the query, as follows – first a table to query:

create table t1
as
with generator as (
	select	--+ materialize
		rownum id
	from dual
	connect by
		level <= 1e4
)
select
	rownum		id1,
	rownum		id2,
	rownum		id,
	lpad(rownum,10)	v1,
	rpad('x',100)	padding
from
	generator	v1,
	generator	v2
where
	rownum <= 1e5
;

create index t1_i1 on t1(id1, id2);

begin
	dbms_stats.gather_table_stats(
		ownname		 => user,
		tabname		 =>'T1',
		method_opt	 => 'for all columns size 1'
	);
end;
/

Then a piece of code to write a nasty query:

set pagesize 0
set feedback off
set termout off

spool temp1.sql

prompt select * from t1 where 1 = 2

select
	'or (id1 = ' || rownum || ' and id2 = ' || (rownum + 1) || ')'
from
	t1
where
	rownum <= 750
union all
select
	'or ( id1 =  ' || (rownum + 1000) || ' and id2 in (' || rownum || ',' || (rownum+1) || '))'
from
	t1
where
	rownum <= 250
;

prompt /

spool off

Here’s an example of the text generated by the code – with the parameters set to 5 and 3 respectively (and notice how I’ve rigged the query so that it doesn’t return any data, whatever the optimizer thinks):

select * from t1 where 1 = 2
or (id1 = 1 and id2 = 2)
or (id1 = 2 and id2 = 3)
or (id1 = 3 and id2 = 4)
or (id1 = 4 and id2 = 5)
or (id1 = 5 and id2 = 6)
or ( id1 =  1001 and id2 in (1,2))
or ( id1 =  1002 and id2 in (2,3))
or ( id1 =  1003 and id2 in (3,4))
/

So here’s the plan from the above query:

---------------------------------------------------------------------------------------
| Id  | Operation                     | Name  | Rows  | Bytes | Cost (%CPU)| Time     |
---------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT              |       |     8 |  1008 |    16   (0)| 00:00:01 |
|   1 |  CONCATENATION                |       |       |       |            |          |
|   2 |   TABLE ACCESS BY INDEX ROWID | T1    |     1 |   126 |     3   (0)| 00:00:01 |
|*  3 |    INDEX RANGE SCAN           | T1_I1 |     1 |       |     2   (0)| 00:00:01 |
|   4 |   TABLE ACCESS BY INDEX ROWID | T1    |     1 |   126 |     3   (0)| 00:00:01 |
|*  5 |    INDEX RANGE SCAN           | T1_I1 |     1 |       |     2   (0)| 00:00:01 |
|   6 |   TABLE ACCESS BY INDEX ROWID | T1    |     1 |   126 |     3   (0)| 00:00:01 |
|*  7 |    INDEX RANGE SCAN           | T1_I1 |     1 |       |     2   (0)| 00:00:01 |
|   8 |   INLIST ITERATOR             |       |       |       |            |          |
|   9 |    TABLE ACCESS BY INDEX ROWID| T1    |     5 |   630 |     7   (0)| 00:00:01 |
|* 10 |     INDEX RANGE SCAN          | T1_I1 |     5 |       |     6   (0)| 00:00:01 |
---------------------------------------------------------------------------------------

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

   3 - access("ID1"=1003)
       filter("ID2"=3 OR "ID2"=4)
   5 - access("ID1"=1002)
       filter((LNNVL("ID1"=1003) OR LNNVL("ID2"=3) AND LNNVL("ID2"=4)) AND
              ("ID2"=2 OR "ID2"=3))
   7 - access("ID1"=1001)
       filter((LNNVL("ID1"=1002) OR LNNVL("ID2"=2) AND LNNVL("ID2"=3)) AND
              (LNNVL("ID1"=1003) OR LNNVL("ID2"=3) AND LNNVL("ID2"=4)) AND ("ID2"=1 OR
              "ID2"=2))
  10 - access(("ID1"=1 AND "ID2"=2 OR "ID1"=2 AND "ID2"=3 OR "ID1"=3 AND
              "ID2"=4 OR "ID1"=4 AND "ID2"=5 OR "ID1"=5 AND "ID2"=6))
       filter((LNNVL("ID1"=1001) OR LNNVL("ID2"=1) AND LNNVL("ID2"=2)) AND
              (LNNVL("ID1"=1002) OR LNNVL("ID2"=2) AND LNNVL("ID2"=3)) AND
              (LNNVL("ID1"=1003) OR LNNVL("ID2"=3) AND LNNVL("ID2"=4)))

As you can see, the first five predicates end up in line 10 of the plan with 10 repetitions (5 * 2) of the lnnvl() function. The last three predicates show up in lines 3, 5, and 7 – and the on each line we see two more lnnvl() calls than on the previous – just imagine, then, how many lnnvl() calls the optimizer will have added to the query plan by the time we have 750 occurrences in the inlist iterator (line 8) and 250 occurrences of the slightly complex predicate. Here are the relevant CPU stats (from v$session_stats) from running the generated script on 11.1.0.7, on Windows 32-bit, 2.8GHz CPU:

Name                                           Value
----                                           -----
recursive cpu usage                            1,848
CPU used when call started                     1,854
CPU used by this session                       1,854
DB time                                        1,870
parse time cpu                                 1,847
parse time elapsed                             1,862

Clearly the parse time is extreme – though not as dramatic as in Dominic’s example; but having set up the first draft of the sample code it’s easy enough to change the number of occurrences of each type of predicate, and it’s pretty easy to make longer in-lists in the more complex of the two types of predicate. It’s not too difficult to get an execution plan that mimics Dominic’s in length and time to parse.

It’s not just the parse times that are interesting when you start doing this, by the way – it’s worth playing around to see what happens. It’s probably best to run the query to pull the plans from memory if you want to see the plans, though – if you try using “explain plan” then you start using memory in the SGA for some of the work: in one of my examples I had to abort the instance after a few minutes.

STS, OFE and SPM

That’s SQL Tuning Sets, optimizer_features_enable, and SQL Plan Management.

There’s a recent post on OTN describing an issue when using SQL Tuning Sets to enforce plan stability when upgrading from 10.2.0.3 to 11.2.0.3 – it doesn’t always work. Here’s a very simple model to demonstrate the type of thing that can happen (the tables are cloned from a completely different demo, so don’t ask why I picked the data they hold):

create table t1
as
select
	trunc((rownum-1)/15)	n1,
	trunc((rownum-1)/15)	n2,
	rpad(rownum,180)	v1
from all_objects
where rownum <= 3000
;

create table t2
as
select
	mod(rownum,200)		n1,
	mod(rownum,200)		n2,
	rpad(rownum,180)	v1
from all_objects
where rownum <= 3000
;

create index t1_i1 on t1(n1);
create index t2_i1 on t2(n1);

execute	dbms_stats.gather_table_stats(user,'t1');
execute	dbms_stats.gather_table_stats(user,'t2');

alter session set optimizer_features_enable = '10.2.0.3';

explain plan for
select
	/*+ ordered use_nl(t1) index(t1) */
	t2.n1, t1.n2
from
	t2,t1
where
	t2.n2 = 45
and	t2.n1 = t1.n1
;

set pagesize 60
set linesize 132
set trimspool on

select * from table(dbms_xplan.display(null,null,'outline'));

You’ll notice I’ve included a directive to set the optimizer_features_enable back to 10.2.0.3. If I run this test on both 10.2.0.3 (real) and 11.2.0.3 (with ofe set) I get the same plans but slightly different outline data.

From 10.2.0.3
-------------------------------------------------------------------------------------
| Id  | Operation                   | Name  | Rows  | Bytes | Cost (%CPU)| Time     |
-------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT            |       |   225 |  3600 |    35   (0)| 00:00:01 |
|   1 |  TABLE ACCESS BY INDEX ROWID| T1    |    15 |   120 |     2   (0)| 00:00:01 |
|   2 |   NESTED LOOPS              |       |   225 |  3600 |    35   (0)| 00:00:01 |
|*  3 |    TABLE ACCESS FULL        | T2    |    15 |   120 |     5   (0)| 00:00:01 |
|*  4 |    INDEX RANGE SCAN         | T1_I1 |    15 |       |     1   (0)| 00:00:01 |
-------------------------------------------------------------------------------------

Outline Data
-------------
  /*+
      BEGIN_OUTLINE_DATA
      USE_NL(@"SEL$1" "T1"@"SEL$1")
      LEADING(@"SEL$1" "T2"@"SEL$1" "T1"@"SEL$1")
      INDEX(@"SEL$1" "T1"@"SEL$1" ("T1"."N1"))
      FULL(@"SEL$1" "T2"@"SEL$1")
      OUTLINE_LEAF(@"SEL$1")
      ALL_ROWS
      OPTIMIZER_FEATURES_ENABLE('10.2.0.3')
      IGNORE_OPTIM_EMBEDDED_HINTS
      END_OUTLINE_DATA
  */

From 11.2.0.3
-------------------------------------------------------------------------------------
| Id  | Operation                   | Name  | Rows  | Bytes | Cost (%CPU)| Time     |
-------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT            |       |   225 |  3600 |    54   (0)| 00:00:01 |
|   1 |  TABLE ACCESS BY INDEX ROWID| T1    |    15 |   120 |     2   (0)| 00:00:01 |
|   2 |   NESTED LOOPS              |       |   225 |  3600 |    54   (0)| 00:00:01 |
|*  3 |    TABLE ACCESS FULL        | T2    |    15 |   120 |    24   (0)| 00:00:01 |
|*  4 |    INDEX RANGE SCAN         | T1_I1 |    15 |       |     1   (0)| 00:00:01 |
-------------------------------------------------------------------------------------

Outline Data
-------------
  /*+
      BEGIN_OUTLINE_DATA
      NLJ_PREFETCH(@"SEL$1" "T1"@"SEL$1")
      USE_NL(@"SEL$1" "T1"@"SEL$1")
      LEADING(@"SEL$1" "T2"@"SEL$1" "T1"@"SEL$1")
      INDEX(@"SEL$1" "T1"@"SEL$1" ("T1"."N1"))
      FULL(@"SEL$1" "T2"@"SEL$1")
      OUTLINE_LEAF(@"SEL$1")
      ALL_ROWS
      DB_VERSION('11.2.0.3')
      OPTIMIZER_FEATURES_ENABLE('10.2.0.3')
      IGNORE_OPTIM_EMBEDDED_HINTS
      END_OUTLINE_DATA
  */

Apart from the appearance of the db_version() hint in 11.2.0.3 the most important difference in the outline data is the hint nlj_prefetch() hint. 11g introduced a new mechanism for nested loop joins called NLJ Batching, at the same time introducing two new hints to allow the optimizer to specify which mechanism a plan should use, prefetch (nlj_prefetch()) or batching (nlj_batching()). Since 10g only does prefetching it doesn’t have (or need) a hint to specify the mechanism.

The outline section data from a plan is basically what Oracle stores as an SQL Plan Baseline – so if I use the approved method to turn the 10g outline data above into the 11g SQL Plan Baseline what’s going to happen to the execution plan when I run the query in the default 11g environment ? It’s easy to demonstrate (at least in this case) by simply cutting and pasting the entire 10g outline into the original SQL statement and generating its plan under 11g; here’s the result:

--------------------------------------------------------------------------------------
| Id  | Operation                    | Name  | Rows  | Bytes | Cost (%CPU)| Time     |
--------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT             |       |   225 |  3600 |    54   (0)| 00:00:01 |
|   1 |  NESTED LOOPS                |       |   225 |  3600 |    54   (0)| 00:00:01 |
|*  2 |   TABLE ACCESS FULL          | T2    |    15 |   120 |    24   (0)| 00:00:01 |
|   3 |   TABLE ACCESS BY INDEX ROWID| T1    |    15 |   120 |     2   (0)| 00:00:01 |
|*  4 |    INDEX RANGE SCAN          | T1_I1 |    15 |       |     1   (0)| 00:00:01 |
--------------------------------------------------------------------------------------

Outline Data
-------------
  /*+
      BEGIN_OUTLINE_DATA
      USE_NL(@"SEL$1" "T1"@"SEL$1")
      LEADING(@"SEL$1" "T2"@"SEL$1" "T1"@"SEL$1")
      INDEX_RS_ASC(@"SEL$1" "T1"@"SEL$1" ("T1"."N1"))
      FULL(@"SEL$1" "T2"@"SEL$1")
      OUTLINE_LEAF(@"SEL$1")
      ALL_ROWS
      DB_VERSION('11.2.0.3')
      OPTIMIZER_FEATURES_ENABLE('10.2.0.3')
      IGNORE_OPTIM_EMBEDDED_HINTS
      END_OUTLINE_DATA
  */

The plan has changed. I was slightly surprised to see in this case that the optimizer used neithor NLJ prefetching, nor NLJ batching, it went all the way back to the traditional nested loop mechanism.

If I had actually captured the original outline hints as an SQL Baseline the optimizer would have found the baseline in the data dictionary, generated this new plan from it, discovered that the plan hash value for this plan didn’t match the plan hash value for the stored plan, and re-optimized the query from scratch - potentially producing a totally different execution plan.

In my example 10g and 11g both wanted to use the nlj_prefetch mechanism when pushed into the nested loop join. 10g, of course, doesn’t have a relevant hint, so I got lucky that 11g wanted to do what 10g had done. In the case of the OP on the OTN forum 11g had decided that it preferred nlj_batching over nlj_prefetch when  attempting to apply the baseline, so the plan hash values didn’t match and the optimizer became free to choose a completely different plan.

Without looking very carefully through all the hints available to 11g I can’t decide whether there are other similar cases to worry about – but if you see 11g ignoring SQL Plan Baselines that have been generated from 10g, then look for operations where 11g has two options (and perhaps two hints) for performing a given operation where 10g has only one option, and perhaps that’s where the problem lies.

Footnotes:

In the case of the OP’s example, a possible workaround could start by setting the hidden parameter “_nlj_batching_enabled”=0; obviously this shouldn’t be done on a production system without approval of Oracle Support, and it’s never a desirable strategy to change a global parameter to fix a local problem – so I’d prefer to set the parameter in a session and generate a new SQL Plan Baseline that would then (probably) include either the nlj_prefetch() hint, or maybe it would turn out to be the no_nlj_batching() hint.

To see what plan (and hints) the SQL Plan Baseline would have generated, the OP enabled SPM tracing using the new event mechanism, in this case:

alter session set events 'trace[RDBMS.SQL_Plan_Management.*]';

-- run, or explain the query here

alter session set events 'trace[RDBMS.SQL_Plan_Management.*] off'; 

Losing it

The example I gave last week showing how a SORT operation in an execution plan might include the work of resolving function calls in your SQL and might, therefore, be reporting much higher resource utilisation than expected reminded me of some problems I’ve had with gaps in execution plans in the past. So I thought I’d give a little demonstration of the way in which the completeness of execution plans can develop over time.

We’ll start with the same two tables I had in last week’s demo.

create table t1
as
select
	rownum 			id,
	lpad(rownum,200)	padding
from	all_objects
where	rownum <= 2500 ; create table t2 as select	* from t1 ; begin 	dbms_stats.gather_table_stats( 		ownname		 => user,
		tabname		 =>'T1',
		method_opt	 => 'for all columns size 1'
	);

	dbms_stats.gather_table_stats(
		ownname		 => user,
		tabname		 =>'T2',
		method_opt	 => 'for all columns size 1'
	);

end;
/

Once we have the tables and stats, we can start running a few very simple queries – I have a sequence of three queries to demonstrate, showing the lovely progression of history:

select
	(select max(t1.id) from t1 where t1.id <= t2.id) id
from	t2
;

select	id
from	t1
minus
select
	(select max(t1.id) from t1 where t1.id <= t2.id) id
from	t2
;

select
	case mod(id,2)
		when 1 then (select max(t1.id) from t1 where t1.id <= t2.id)  		when 0 then (select max(t1.id) from t1 where t1.id >= t2.id)
	end id
from	t2
;

The first, and simplest query, demonstrates 8i failing to produce the right plan – but 9i handles it correctly:

Plan from 8.1.7.4
  Id  Par  Pos  Ins Plan
---- ---- ---- ---- ----------------------------------------------------------------------
   0         3        SELECT STATEMENT (all_rows)     Cost (3,2500,10000)
   1    0    1    2     TABLE ACCESS (analyzed)  TEST_USER T2 (full)  Cost (3,2500,10000)

Plan from 9.2.0.8
-------------------------------------------------------------------------
| Id  | Operation            |  Name       | Rows  | Bytes | Cost (%CPU)|
-------------------------------------------------------------------------
|   0 | SELECT STATEMENT     |             |  2500 | 10000 |    12   (9)|
|   1 |  SORT AGGREGATE      |             |     1 |     4 |            |
|*  2 |   TABLE ACCESS FULL  | T1          |   125 |   500 |    12   (9)|
|   3 |  TABLE ACCESS FULL   | T2          |  2500 | 10000 |    12   (9)|
-------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------
   2 - filter("T1"."ID"<=:B1)

The second query, including a section of SQL that 9i handled properly, shows an incomplete plan in 9i and 10g, but gets a complete plan in 11g. (The row estimate of 125 in line 5 of the second plan is the usual 5% estimate for a range-based predicate against an unknown value: 5% of 2,500 is 125).

Plan from 9.2.0.8 / 10.2.0.5
-------------------------------------------------------------------------
| Id  | Operation            |  Name       | Rows  | Bytes | Cost (%CPU)|
-------------------------------------------------------------------------
|   0 | SELECT STATEMENT     |             |  2500 | 20000 |    26  (58)|
|   1 |  MINUS               |             |       |       |            |
|   2 |   SORT UNIQUE        |             |  2500 | 10000 |    13  (16)|
|   3 |    TABLE ACCESS FULL | T1          |  2500 | 10000 |    12   (9)|
|   4 |   SORT UNIQUE        |             |  2500 | 10000 |    13  (16)|
|   5 |    TABLE ACCESS FULL | T2          |  2500 | 10000 |    12   (9)|
-------------------------------------------------------------------------

Plan from 11.1.0.7
----------------------------------------------------------------------------
| Id  | Operation           | Name | Rows  | Bytes | Cost (%CPU)| Time     |
----------------------------------------------------------------------------
|   0 | SELECT STATEMENT    |      |  2500 | 20000 |    25  (56)| 00:00:01 |
|   1 |  MINUS              |      |       |       |            |          |
|   2 |   SORT UNIQUE       |      |  2500 | 10000 |    12   (9)| 00:00:01 |
|   3 |    TABLE ACCESS FULL| T1   |  2500 | 10000 |    11   (0)| 00:00:01 |
|   4 |   SORT AGGREGATE    |      |     1 |     4 |            |          |
|*  5 |    TABLE ACCESS FULL| T1   |   125 |   500 |    11   (0)| 00:00:01 |
|   6 |   SORT UNIQUE       |      |  2500 | 10000 |    12   (9)| 00:00:01 |
|   7 |    TABLE ACCESS FULL| T2   |  2500 | 10000 |    11   (0)| 00:00:01 |
----------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------
   5 - filter("T1"."ID"<=:B1)

But if we start to hide subqueries inside CASE operators (decodes would do the same), 11g starts to get it a little wrong, as shown by the third example. The depth column of the plan_table can be calculated incorrectly, in this case giving the impression that line 6 is a descendent of line 5. (Funnily enough, 9i gets this example right because the code to display the plan from the plan_table uses the old “connect by” query on id and parent_id rather than the calculated depth column.

Plan from 11.1.0.7 / 11.2.0.3
------------------------------------------------------------------------------
| Id  | Operation             | Name | Rows  | Bytes | Cost (%CPU)| Time     |
------------------------------------------------------------------------------
|   0 | SELECT STATEMENT      |      |  2500 | 20000 |    25  (56)| 00:00:01 |
|   1 |  MINUS                |      |       |       |            |          |
|   2 |   SORT UNIQUE         |      |  2500 | 10000 |    12   (9)| 00:00:01 |
|   3 |    TABLE ACCESS FULL  | T1   |  2500 | 10000 |    11   (0)| 00:00:01 |
|   4 |   SORT AGGREGATE      |      |     1 |     4 |            |          |
|*  5 |    TABLE ACCESS FULL  | T1   |   125 |   500 |    11   (0)| 00:00:01 |
|   6 |     SORT AGGREGATE    |      |     1 |     4 |            |          |
|*  7 |      TABLE ACCESS FULL| T1   |   125 |   500 |    11   (0)| 00:00:01 |
|   8 |   SORT UNIQUE         |      |  2500 | 10000 |    12   (9)| 00:00:01 |
|   9 |    TABLE ACCESS FULL  | T2   |  2500 | 10000 |    11   (0)| 00:00:01 |
------------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------
   5 - filter("T1"."ID"<=:B1)    7 - filter("T1"."ID">=:B1)

You might note, by the way, that in all these examples the estimated COST of the plans is very misleading. The optimizer has made no attempt to allow for the cost of the repeated execution of the scalar subqueries. This doesn’t really matter, of course, for very simple queries like this, but it could make a big difference if something of this sort were embedded in the middle of a more complex statement.

Next time you have to unravel the execution plan for a complex query with scalar subqueries floating around the place – there may be bits of the plan that you can’t see, or that aren’t doing quite what you think you’re being told. When interpretation gets tough make sure you track through the query and the plan to see if the plan is likely to be a complete and truthful representation of what the statement has to do.

Sorting

Here’s a little quirk of execution plans that came up recently on the Oak Table network. If you call a function in a query, and do some sorting with the results, where does the work of calling the function get reported in the execution plan if you trace the query or look at the in-memory rowsource execution stats. Let’s take a look at a simple example:

create table t1
as
select
	rownum 			id,
	lpad(rownum,200)	padding
from	all_objects
where	rownum <= 2500
;

create table t2
as
select	* from t1
;

-- collect stats

create or replace function f (i_target in number)
return number
as
	m_target	number;
begin
	select max(id) into m_target from t1 where id <= i_target;
	return m_target;
end;
/

So I’ve got two tables with exactly the same data and a function that will do a full tablescan of t1 (which is going to be 75 blocks) and return the original input (assuming the input was between 1 and 2,500). Here’s the query I want to run (and it will return no rows), followed by the base execution plan.

select	/*+ gather_plan_statistics */
	id
from 	t1
minus
select
	f(id)
from	t2
;

select * from table(dbms_xplan.display_cursor(null,null,'basic +rows'));

--------------------------------------------
| Id  | Operation           | Name | Rows  |
--------------------------------------------
|   0 | SELECT STATEMENT    |      |       |
|   1 |  MINUS              |      |       |
|   2 |   SORT UNIQUE       |      |  2500 |
|   3 |    TABLE ACCESS FULL| T1   |  2500 |
|   4 |   SORT UNIQUE       |      |  2500 |
|   5 |    TABLE ACCESS FULL| T2   |  2500 |
--------------------------------------------

Because of the call to f() in the select against t2, I’m going to call the function 2,500 times and incur a load of buffer reads (2,500 * 75) doing so. Where will those buffer gets and the attendant CPU appear in the plan ? This example is by no means an exhaustive analysis of all the possible options when you include functions in your select list, but in this particular case the function isn’t called until we run the SORT UNIQUE operation at line 4:

select * from table(dbms_xplan.display_cursor(null,null,'allstats last projection'));

-----------------------------------------------------------------------------------------------------------------
| Id  | Operation           | Name | Starts | E-Rows | A-Rows |   A-Time   | Buffers |  OMem |  1Mem | Used-Mem |
-----------------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT    |      |      1 |        |      0 |00:00:00.54 |     187K|       |       |          |
|   1 |  MINUS              |      |      1 |        |      0 |00:00:00.54 |     187K|       |       |          |
|   2 |   SORT UNIQUE       |      |      1 |   2500 |   2500 |00:00:00.01 |      75 | 70656 | 70656 |63488  (0)|
|   3 |    TABLE ACCESS FULL| T1   |      1 |   2500 |   2500 |00:00:00.01 |      75 |       |       |          |
|   4 |   SORT UNIQUE       |      |      1 |   2500 |   2500 |00:00:00.54 |     187K| 70656 | 70656 |63488  (0)|
|   5 |    TABLE ACCESS FULL| T2   |      1 |   2500 |   2500 |00:00:00.01 |      75 |       |       |          |
-----------------------------------------------------------------------------------------------------------------

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

   1 - STRDEF[22]
   2 - (#keys=1) "ID"[NUMBER,22]
   3 - "ID"[NUMBER,22]
   4 - (#keys=1) "F"("ID")[22]
   5 - "ID"[NUMBER,22]

The 187K buffer gets for the function calls (and any other resources) appear at line 4 of the plan, when you might have expected them to appear in line5 as part of the tablescan. This observation can be confirmed by checking the column projection information – the output from line 5 is the “ID”, the output from line 4 includes “F”(“ID”). I don’t often look at the projection information, but it’s nice to know that sometimes it can give you some ideas of what’s going on when the row source execution stats don’t seem to be what you were expecting.

Footnote: The same sort of effect appears with scalar subqueries in the select lists, although in any  recent versions of Oracle the plan for the scalar subquery appears in the main plan (although sometimes in a counter-intuitive position) and will give you a much better idea of where and why the work is being done.

 

Update Error

When doing updates with statements that use correlated subqueries, it’s important to make sure that your brackets (parentheses) are in the right place. Here are two statements that look fairly similar but have remarkably different results – and sometimes people don’t realise how different the statements are:

update t1
set
        padding = (
                select
                        t2.padding
                from    t2
                where   t2.id = t1.id
        )
where   t1.small_vc <= lpad(20,10,'0')
;

update t1
set
        padding = (
                select
                        t2.padding
                from    t2
                where   t2.id = t1.id
                and     t1.small_vc <= lpad(20,10,'0')
        )
;

The first statement will update rows in t1 where t1.small_vc <= lpad(20,10,’0′), copying the value of padding from t2 where (if) the id columns match, but setting t1.padding to null if there is no match.

The second statement will update every single row in t1 – some of the rows will probably be updated as expected (i.e. to get the same result as the first statement) but every row where t1.small_vc is greater than lpad(20,10,’0′) will have the padding column set to null.

Originally I created this little demo to respond to a question on OTN – but when I ran it with rowsource execution statistics enabled, I discovered that it also happened to demonstrate an odd bug in that feature – even in 11.2.0.3. Here are the two plans corresponding to the above two statements. The update is supposed to update 20 rows in t1, the incorrect form of the code will update all 10,000 rows in the table:

20 rows updated.

PLAN_TABLE_OUTPUT
------------------------------------------------------------------------------------------------------------------------
SQL_ID  73tz2pqv4z8rc, child number 0
-------------------------------------
update t1 set  padding = (   select    t2.padding   from t2   where
t2.id = t1.id  ) where t1.small_vc <= lpad(20,10,'0')

Plan hash value: 417405447

------------------------------------------------------------------------------------------------
| Id  | Operation                    | Name  | Starts | E-Rows | A-Rows |   A-Time   | Buffers |
------------------------------------------------------------------------------------------------
|   0 | UPDATE STATEMENT             |       |      1 |        |      0 |00:00:00.01 |     219 |
|   1 |  UPDATE                      | T1    |      1 |        |      0 |00:00:00.01 |     219 |
|*  2 |   TABLE ACCESS FULL          | T1    |      1 |     20 |     20 |00:00:00.01 |     173 |
|   3 |   TABLE ACCESS BY INDEX ROWID| T2    |     20 |      1 |     20 |00:00:00.01 |      45 |
|*  4 |    INDEX UNIQUE SCAN         | T2_PK |     20 |      1 |     20 |00:00:00.01 |      25 |
------------------------------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------
   2 - filter("T1"."SMALL_VC"<='0000000020')
   4 - access("T2"."ID"=:B1)

10000 rows updated.

PLAN_TABLE_OUTPUT
------------------------------------------------------------------------------------------------------------------------
SQL_ID  ax22zpj8xdwpn, child number 0
-------------------------------------
update t1 set  padding = (   select    t2.padding   from t2   where
t2.id = t1.id   and t1.small_vc <= lpad(20,10,'0')  )

Plan hash value: 2442374960

-------------------------------------------------------------------------------------------------
| Id  | Operation                     | Name  | Starts | E-Rows | A-Rows |   A-Time   | Buffers |
-------------------------------------------------------------------------------------------------
|   0 | UPDATE STATEMENT              |       |      3 |        |      0 |00:00:00.27 |   21576 |
|   1 |  UPDATE                       | T1    |      3 |        |      0 |00:00:00.27 |   21576 |
|   2 |   TABLE ACCESS FULL           | T1    |      3 |  10000 |  29692 |00:00:00.03 |     514 |
|*  3 |   FILTER                      |       |  19692 |        |     40 |00:00:00.01 |      85 |
|   4 |    TABLE ACCESS BY INDEX ROWID| T2    |     40 |      1 |     40 |00:00:00.01 |      85 |
|*  5 |     INDEX UNIQUE SCAN         | T2_PK |     40 |      1 |     40 |00:00:00.01 |      45 |
-------------------------------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------
   3 - filter(:B1<='0000000020')
   5 - access("T2"."ID"=:B1)

Note, in both cases, how the number of rows reported in the update operation (line 1) is zero although we might expect it to match the A-rows value reported in the table access full operation (line 2) which tells us how many rows were identified for update. But something strange has happened in the line reporting the table access full in the second case – clearly there’s a bug somewhere because there were only 10,000 rows in the table, yet the tablescan has (apparently) identified 29,692 rows for update.

Not only is the tablescan line reporting silly numbers, the filter line is as well (because that should only start 10,000 times – once per row in the table) moreover the subquery lines (4 and 5) should only start 20 times each because the filter should eliminate the need to run the subquery for all rows except the 20 where “T1″.”SMALL_VC”<=’0000000020. Even stranger is the fact that when I ran this test several times in a row (recreating the tables each time), the starts and A-rows values for the filter and table access full lines changed (decreasing) every time!

It took me a little while to figure out what was going on – but the doubling of the starts for the subquery gave me a hint, confirmed when I took a snapshot of how the session stats changed when I ran the second update. It’s just another variant of the odd “write consistency” behaviour that can appear when running tablescan through a large volume of data and updating it (although I have to say that I hadn’t seen it happening for a mere 10,000 rows before).  Oracle starts the tablescan and update, and after a while decides that it has to rollback and restart the update – the 20 rows that were subject to the subquery were the first 20 rows of the table, which is why they were almost sure to trigger the subquery twice each, had they appeared half way through the table the effect might not have been so consistent).

Footnote:

If you want to repeat my test for yourselves, here’s the code to generate the data sets:

create table t1
as
with generator as (
        select  --+ materialize
                rownum id
        from dual
        connect by
                level <= 1e4
)
select
        rownum                  id,
        lpad(rownum,10,'0')     small_vc,
        rpad('x',100)           padding
from
        generator       v1,
        generator       v2
where
        rownum <= 1e4
;

create table t2
as
select * from t1
;

alter table t1 add constraint t1_pk primary key(id);
alter table t2 add constraint t2_pk primary key(id);

Plan Order

The previous post reminded me of another (fairly special) case where the order of operations in an execution plan seems to be wrong according to the “traditional” strategy for reading execution plans. Here’s a simple select statement with its execution plan to demonstrate the point:

select
	small_vc
from
	t1
where
	exists (
		select	null
		from	f1
		where	f1.id       = t1.id
		and	f1.small_vc = t1.small_vc
	)
and
	exists (
		select	null
		from	f2
		where	f2.id = 21
	)
;

------------------------------------------------------------------------------
| Id  | Operation             | Name  | Rows  | Bytes | Cost (%CPU)| Time     |
-------------------------------------------------------------------------------
|   0 | SELECT STATEMENT      |       |     1 |    29 |    51   (2)| 00:00:01 |
|*  1 |  FILTER               |       |       |       |            |          |
|*  2 |   HASH JOIN RIGHT SEMI|       |     1 |    29 |    51   (2)| 00:00:01 |
|   3 |    TABLE ACCESS FULL  | F1    |    20 |   280 |     2   (0)| 00:00:01 |
|   4 |    TABLE ACCESS FULL  | T1    | 10000 |   146K|    48   (0)| 00:00:01 |
|*  5 |   INDEX UNIQUE SCAN   | F2_PK |     1 |    13 |     0   (0)| 00:00:01 |
-------------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------
   1 - filter( EXISTS (SELECT /*+ */ 0 FROM "F2" "F2" WHERE "F2"."ID"=21))
   2 - access("F1"."ID"="T1"."ID" AND "F1"."SMALL_VC"="T1"."SMALL_VC")
   5 - access("F2"."ID"=21)

The traditional strategy for reading this plan (recursively operate the child rows of each parent row in the order that they appear) would say: we scan table F1 and buildilng a hash table in memory, then scan table T1 probing the hash table to perform the hash semi join of line 2. For each row that survives the hash join, the filter operation at line 1 tells us to run the subquery against F2 to see if the row should be passed forward as an output of the select statement.

You might like to pause briefly at this point to convince yourself that this is the way we usually interpret the indentation of an execution plan.

It’s not what happens in this special case. Notice that the second subquery isn’t correlated – it need only run once for Oracle to decide whether or not it will return any data. As a side effect of this special case, the plan operates “upside down”. Here’s the same execution plan pulled from memory after enabling rowsource execution statistics. It’s implrtant to be aware that in my test case the data in F2 doesn’t have a row where id = 21.

PLAN_TABLE_OUTPUT
------------------------------------------------------------------------------------------------------------------------
SQL_ID  5bd1m72cz4awy, child number 0
-------------------------------------
select  small_vc from  t1 where  exists (   select null   from f1   where f1.id       = t1.id   and
f1.small_vc = t1.small_vc  ) and  exists (   select null   from f2   where f2.id = 21  )

Plan hash value: 1423735592

--------------------------------------------------------------------------------------------------------------------
| Id  | Operation             | Name  | Starts | E-Rows | A-Rows |   A-Time   | Buffers |  OMem |  1Mem | Used-Mem |
--------------------------------------------------------------------------------------------------------------------
|*  1 |  FILTER               |       |      1 |        |      0 |00:00:00.01 |       1 |       |       |          |
|*  2 |   HASH JOIN RIGHT SEMI|       |      0 |      1 |      0 |00:00:00.01 |       0 |   825K|   825K|          |
|   3 |    TABLE ACCESS FULL  | F1    |      0 |     20 |      0 |00:00:00.01 |       0 |       |       |          |
|   4 |    TABLE ACCESS FULL  | T1    |      0 |  10000 |      0 |00:00:00.01 |       0 |       |       |          |
|*  5 |   INDEX UNIQUE SCAN   | F2_PK |      1 |      1 |      0 |00:00:00.01 |       1 |       |       |          |
--------------------------------------------------------------------------------------------------------------------

Predicate Information (identified by operation id):
---------------------------------------------------
   1 - filter( IS NOT NULL)
   2 - access("F1"."ID"="T1"."ID" AND "F1"."SMALL_VC"="T1"."SMALL_VC")
   5 - access("F2"."ID"=21)

Look carefully at the starts column. Line 1 (filter) started once; line 5 (the second child to the filter) started once and returned no rows; line 2 (the first child to the filter) never started – it didn’t have to because by this point Oracle had already determined that any data it generated would be eliminated by the non-existence of a match from line 5.

Summary

There are a few special case plans where the normal “first child first” rule (“… more what you’d call guidelines than actual rules.” — Captain Barbossa) for reading execution plans doesn’t apply. The “constant subquery” introduces one of them.

Footnote:

If you want to repeat the experiment on different versions of Oracle, here’s the code to generate my test data:

create table t1
as
with generator as (
	select	--+ materialize
		rownum 	id
	from	all_objects
	where	rownum <= 3000
)
select
	rownum			id,
	lpad(rownum,10,'0')	small_vc,
	rpad('x',100)		padding
from
	generator	v1,
	generator	v2
where
	rownum <= 10000
;

create table f1 as select * from t1 where id <= 20;
create table f2 as select * from t1 where id <= 20;

alter table f1 add constraint f1_pk primary key(id);
alter table f2 add constraint f2_pk primary key(id);

-- collect stats (compute, no histograms)

Plan timing

I’ve copied the following question up from a recent comment because it’s a useful generic type of question, and I think I can answer it in the few minutes I have to spare.

Hi Jonathan. I have a query plan where I cannot explain how time adds up. I did the ALTER SESSION trick but it changed nothing. I ran this, and got the following plan. I have two questions (I appoligize for not being able to format this code and plan but I saw not formatting buttons on the insert box).

1) @ step #8 in the plan, the query jumps to 3 and 1/2 minutes. This step says VIEW but gives no indication of what it did that actually took 3 and 1/2 minutes. Can you explain or give me some idea how to find out what is being done on this line that takes that long. Especially with so few rows.

2) the total elapsed time of the query was 3 minutes 45 seconds. This jives with step #1 that says 3:44.54. But if A-TIME is supposed to be among other things, the sum of child steps, then how to we explain step #2. Step #2 says 3 minutes 3 minutes 44 seconds. But the sum of its child steps (#3 and #8) is7 minutes and 25 seconds. Did this query do these steps “in parallel” so to speak? Or is there something really off in the numbers and if so how to I prove it?

This is not something that is super pressing but I sure would like to be able to explain the differences to people. It is making it somewhat harder to get people to believe I know what I am doing when I cannot such obvious issues as these two things.

Thanks, Kevin Meade

Fortunately Kevin included enough information to allow me to understand what was going on. In this case that means Here’s the query and the execution plan pulled from memory – showing the execution statistics. As follows:

ALTER SESSION SET STATISTICS_LEVEL=ALL
/

drop table kevtemp1
/

create table kevtemp1
nologging
as
SELECT SRCE_EFF_START_TMSP,
       AGGREGATECLAIMUID
FROM (
     SELECT  A.AGGREGATECLAIMUID,
             A.SNAPSHOT_DT,
             MAX(A.SRCE_EFF_START_TMSP) SRCE_EFF_START_TMSP
     FROM (SELECT PI.AGGREGATECLAIMUID,
                  PI.SRCE_EFF_START_TMSP,
                  (SELECT DISTINCT BW.SNAPSHOT_DT
                   FROM RRS_SHR.RRS_ETL_BATCH_WINDOW BW, RRS_SHR.RRS_LOAD_STATUS RLS
                   WHERE RLS.ASTG_LOAD_STATUS = 'STARTED'
                   AND RLS.SNAPSHOT_DT = BW.SNAPSHOT_DT
                   AND BW.RPTG_WINDOW_TYPE = 'D'
                   AND BW.OBJECT_NM = 'R_AGGREGATE_CLAIM_SEED'
                   AND PI.SRCE_EFF_START_TMSP
                       BETWEEN
                       BW.BEGIN_TMSP
                       AND
                       BW.END_TMSP
                  ) AS SNAPSHOT_DT
           FROM RRS_PSTG.P_PCD_AGGREGATECLAIM PI
           WHERE PI.BATCH_ID IN
                 (SELECT src_batch_id
                  FROM batch_processing_queue
                  WHERE dm_batch_id =
                        batch_id_pkg.get_current_batch_id('PCD','ATM')
                 )
          ) A
          GROUP BY A.AGGREGATECLAIMUID, A.SNAPSHOT_DT
     )
/

Table created.

Elapsed: 00:03:45.14

Plan hash value: 3515505567

----------------------------------------------------------------------------------------------------------------------------------------------------------------------
| Id  | Operation                       | Name                        | Starts | E-Rows | A-Rows |   A-Time   | Buffers | Reads  | Writes |  OMem |  1Mem | Used-Mem |
----------------------------------------------------------------------------------------------------------------------------------------------------------------------
|   0 | CREATE TABLE STATEMENT          |                             |      1 |        |      0 |00:03:44.54 |     246K|   8389 |    128 |       |       |          |
|   1 |  LOAD AS SELECT                 |                             |      1 |        |      0 |00:03:44.54 |     246K|   8389 |    128 |   530K|   530K|  530K (0)|
|   2 |   HASH GROUP BY                 |                             |      1 |  84487 |  48482 |00:03:44.41 |     245K|   8386 |      0 |  3128K|  1284K| 3538K (0)|
|   3 |    HASH UNIQUE                  |                             |  33524 |      1 |  33524 |00:03:40.98 |     236K|     12 |      0 |  1270K|  1270K|  523K (0)|
|   4 |     NESTED LOOPS                |                             |  33524 |      1 |  33524 |00:00:08.35 |     236K|     12 |      0 |       |       |          |
|*  5 |      TABLE ACCESS BY INDEX ROWID| RRS_ETL_BATCH_WINDOW        |  33524 |     11 |  33524 |00:00:07.84 |     203K|      9 |      0 |       |       |          |
|*  6 |       INDEX RANGE SCAN          | IDX1_RRS_ETL_BATCH_WINDOW   |  33524 |     41 |   5414K|00:00:04.09 |   86482 |      5 |      0 |       |       |          |
|*  7 |      INDEX UNIQUE SCAN          | IUK2_RRS_LOAD_STATUS        |  33524 |      1 |  33524 |00:00:00.31 |   33535 |      3 |      0 |       |       |          |
|   8 |    VIEW                         |                             |      1 |  84487 |  48484 |00:03:43.99 |     245K|   8386 |      0 |       |       |          |
|*  9 |     HASH JOIN                   |                             |      1 |  84487 |  48484 |00:00:02.63 |    9186 |   8374 |      0 |  1023K|  1023K| 1243K (0)|
|* 10 |      INDEX RANGE SCAN           | IAK1_BATCH_PROCESSING_QUEUE |      1 |      5 |    102 |00:00:00.22 |     855 |     44 |      0 |       |       |          |
|  11 |      TABLE ACCESS FULL          | P_PCD_AGGREGATECLAIM        |      1 |   1536K|   1536K|00:00:01.47 |    8331 |   8330 |      0 |       |       |          |
----------------------------------------------------------------------------------------------------------------------------------------------------------------------

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

   5 - filter(("BW"."BEGIN_TMSP"=:B1)
   7 - access("RLS"."SNAPSHOT_DT"="BW"."SNAPSHOT_DT" AND "RLS"."ASTG_LOAD_STATUS"='STARTED')
   9 - access("PI"."BATCH_ID"="SRC_BATCH_ID")
  10 - access("DM_BATCH_ID"="BATCH_ID_PKG"."GET_CURRENT_BATCH_ID"('PCD','ATM'))

46 rows selected.

Elapsed: 00:00:01.75

Working through the layers of the query, from the outside towards the middle, we have a simple select from an inline view. The inline view, however, is an aggregate view that selects from another inline view. One of the “columns” of the innermost inline view is an scalar subquery that joins two tables, and the view also uses an IN subquery. So we need to identify all these pieces in the execution plan.

Lines 9 – 11 of the plan show us that the IN subquery of the innermost view has been unnested, producing a hash join. The VIEW operator tells us that this join has been optimized as a “leaf” query block. Lines 3 – 7 give us the separately optimized execution plan for the “select distinct” inline scalar subquery; I am slightly surprised that this part of the plan doesn’t appear after the VIEW operator at line 8, indented at the same level as line 9, since it is a plan that generates a value for each row returned in the view.

Note: although the plan in lines 3 – 7 could be executed once for each row returned by the plan in lines 9 – 11, the number of executions could (and in this case is) fewer than the worst case thanks to scalar subquery caching.

The location of the scalar subquery in the overall plan does make it harder to understand the various time and resource usage figures – but once you understand what the query has to do, it is easier to work out why the numbers have a dislocated look. The time in line 8 is 3:43.99 because it includes the time in line 9 (2.63 seconds) that generates 48,484 rows, plus the time in line 3 (3:40.98) that comes from running the scalar subquery 33,524 times.

Summary

Subqueries can appear in various places in execution plans – when they are scalar subqueries representing columns in the select list, they appear ABOVE the query block that calls them. This can be very confusing when you’re trying to follow the trail of where the time and resources are first used when you’ve collected rowsource execution statistics.

count(*)

I came across a nice bit of code on OTN recently that someone had written several years ago (in 2007, in fact)  to demonstrate the different ways in which the optimizer would handle “select count({something}) from table;”. If you want to copy and repeat the test code, you may need to adjust it slightly – it references a type vc2s, which I changed to dbms_stats.chararray, and it references a plan table called toad_plan_table, which I replaced with references to the standard plan_table (getting rid of the truncate as I did so).

The code simply executes a call to explain plan for different statements, then extracts the projection information for the “sort aggregate” line of the execution plan (examining the operation and options columns to do so). The thing that particularly surprised me was that there was a difference between the following two queries:
(more…)

Debugging

One of my recent assignments involved a company that had run into some performance problems after upgrading from 10.2.0.3 to 11.2.0.2. We had spent half an hour on the phone discussing the system before I had arrived, and I’d made a couple of suggestions that had solved most of their problems before I got on site – but they still wanted me to come in and give them some specific ideas about why the critical part of the solution had helped.

The most critical piece of advice I had given them (after listening very carefully to their description of the system) was to get rid of ALL the histograms they had on their system, and then watch very carefully for any signs that they might need to re-introduce a handful of histograms over the next few weeks.

One of their critical queries completed in less that 2 seconds when histograms were removed, but took 33 seconds to complete when histograms were in place. With their permission, the following notes record my investigation of this puzzle, the underlying Oracle bug (possibly not yet documented) that caused it, and the optimum workaround that was available to them.
(more…)

ANSI Outer 2

A comment on a recent post of mine pointed me to a question on the OTN SQL and PL/SQL Forum where someone had presented a well-written test case of an odd pattern of behaviour in ANSI SQL. I made a couple of brief comments on the thread, but thought it worth highlighting here as well. The scripts to create the required tables (plus a few extras) are all available on OTN. If you create only the four tables needed and all their indexes you will need about 1.3GB of space.

The core of the problem is this: there is a three table join which does a hash join involving an index fast full scan on a particular index; when you add a fourth table to the join this fast full scan turns into a full tablescan for no obvious reason. Here are the queries, with the plans that I got when running 10.2.0.3. (My final plan is slightly different from the plan shown on OTN – I have a right outer hash join to the last table where the OP had a nested loop outer – but the difference is not significant). The queries, with their execution plans, are below- the three table join first:
(more…)

PK Problem

I have been saying for a very long time (probably since some time in the last century) that if you want to add a primary key (or unique) constraint to a table where there might be some duplicate data then one of the best strategies for doing so might be to create a non-unique index (with the online option), then add the constraint in the state enable novalidate, and then validate the constraint. For example:

create table t1
as
select
	*
from
	all_objects
;

create index t1_i1 on t1(object_id) online;
-- collect stats
alter table t1 add constraint t1_pk primary key(object_id) enable novalidate;
alter table t1 modify constraint t1_pk validate;

(more…)

Unique Fail

As in – how come a unique (or primary key) index is predicted to return more than one row using a unique scan. Here’s and example (running on 10.2.0.3 – but the same type of thing happens on newer versions):
(more…)

Subpartition stats

You might have expected the following query ought to run reasonably efficiently, after all it seems to be targeted very accurately at precisely the few rows of information I’m interested in:

select
	column_name,
	avg_col_len
from
	dba_subpart_col_statistics
where
	owner             = 'TEST_USER'
and 	table_name        = 'TEST_COMP'
and	subpartition_name = 'P_MAX_D'

(more…)

Subquery Factoring

I have a small collection of postings where I’ve described anomalies or limitations in subquery factoring (the “with subquery”, or Common Table Expression (CTE) to give it the official ANSI name). Here’s another example of Oracle’s code not behaving consistently. You may recognise the basic query from yesterday’s example of logical tuning – so I won’t reprint the code to generate the data sets. This examples in this note were created on 11.2.0.2 – we start with a simple query and its execution plan:
(more…)

First_rows hash

Just like my posting on an index hash, this posting is about a problem as well as being about a hash join. The article has its roots in a question posted on the OTN database forum, where a user has shown us the following execution plan:

---------------------------------------------------------------------------------------------------------
| Id  | Operation                     | Name                    | Rows  | Bytes | Cost (%CPU)| Time     |
---------------------------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT              |                         |    14 |   896 |    63   (7)| 00:00:01 |
|   1 |  SORT GROUP BY                |                         |    14 |   896 |    63   (7)| 00:00:01 |
|   2 |   NESTED LOOPS                |                         |       |       |            |          |
|   3 |    NESTED LOOPS               |                         |    14 |   896 |    62   (5)| 00:00:01 |
|*  4 |     HASH JOIN                 |                         |    14 |   280 |    48   (7)| 00:00:01 |
|   5 |      VIEW                     | V_SALES_ALL             |   200 |  1800 |     4   (0)| 00:00:01 |
|   6 |       UNION-ALL               |                         |       |       |            |          |
|   7 |        INDEX FAST FULL SCAN   | PRODUCTS_DATES_IDX      |   100 |   900 |     2   (0)| 00:00:01 |
|   8 |        INDEX FAST FULL SCAN   | PRODUCTS_DATES_IDX_HARD |   100 |   900 |     2   (0)| 00:00:01 |
|*  9 |      VIEW                     | index$_join$_003        |  2238 | 24618 |    44   (7)| 00:00:01 |
|* 10 |       HASH JOIN               |                         |       |       |            |          |
|* 11 |        INDEX RANGE SCAN       | PRODUCTS_GF_INDEX2      |  2238 | 24618 |     6   (0)| 00:00:01 |
|  12 |        INDEX FAST FULL SCAN   | PRODUCTS_GF_PK          |  2238 | 24618 |    45   (3)| 00:00:01 |
|* 13 |     INDEX UNIQUE SCAN         | DATES_PK                |     1 |       |     0   (0)| 00:00:01 |
|  14 |    TABLE ACCESS BY INDEX ROWID| DATES                   |     1 |    44 |     1   (0)| 00:00:01 |
---------------------------------------------------------------------------------------------------------

(more…)