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Global Index Maintenance – Pre 12c (Unwashed and Somewhat Slightly Dazed) July 26, 2013

Posted by Richard Foote in Global Indexes, Oracle Indexes, Partitioning.
1 comment so far

Before I discuss another Oracle Database 12c new feature, Asynchronous Global Index Maintenance, thought it might be worthwhile discussing how Global Indexes were handled prior to 12c.

I’ll begin by creating and populating a simple range partitioned table:

SQL> create table muse (id number, code number, name varchar2(30)) partition by range (id)
(partition muse1 values less than (1000001), partition muse2 values less than (2000001), partition muse3 values less than (maxvalue));

Table created.

SQL> insert into muse select rownum, mod(rownum,100000), 'DAVID BOWIE' from dual connect by level <= 3000000;

3000000 rows created.

SQL> commit;

Commit complete.

SQL> exec dbms_stats.gather_table_stats(ownname=>user, tabname=>'MUSE', estimate_percent=>null, method_opt=>'FOR ALL COLUMNS SIZE 1');

PL/SQL procedure successfully completed.

I’ll now create two global indexes, one non-partitioned, the other partitioned:

SQL> create index muse_id_i on muse(id);
Index created.

SQL> create index muse_code_i on muse(code) global partition by range(code)
(partition code_p1 values less than (50000), partition code_p2 values less than (maxvalue));

Index created.

SQL> select index_name, null partition_name, num_rows, s.blocks, leaf_blocks, status
from dba_indexes i, dba_segments s where i.index_name = s.segment_name and table_name='MUSE' and partitioned = 'NO'
union select index_name, i.partition_name, num_rows, s.blocks, leaf_blocks, status
from dba_ind_partitions i, dba_segments s where i.partition_name = s.partition_name and index_name like 'MUSE%';

INDEX_NAME      PARTITION_NAME    NUM_ROWS     BLOCKS LEAF_BLOCKS STATUS
--------------- --------------- ---------- ---------- ----------- --------
MUSE_CODE_I     CODE_P1            1500000       4224        4135 USABLE
MUSE_CODE_I     CODE_P2            1500000       4352        4177 USABLE
MUSE_ID_I                          3000000       9216        8633 VALID

So we currently have two happy chappy global indexes. I’m now however going to drop one of the table partitions without updating the global indexes and monitor both the db block gets and amount of redo that gets generated:

SQL> select n.name, s.value from v$sesstat s, v$statname n where s.statistic# = n.statistic# and (n.name = 'redo size' or n.name = 'db block gets') and s.sid=129;

NAME               VALUE
------------- ----------
db block gets     457109
redo size      234309652

SQL> alter table muse drop partition muse1;

Table altered.

Elapsed: 00:00:00.66

SQL> select n.name, s.value from v$sesstat s, v$statname n where s.statistic# = n.statistic# and (n.name = 'redo size' or n.name = 'db block gets') and s.sid=129;

NAME           VALUE
-------------- ----------
db block gets      457165
redo size       234320512

We notice the operation completed very quickly and generated minimal db block gets (just 56) and redo (just 10860 bytes). However, this of course comes at a price:

SQL> select index_name, null partition_name, num_rows, leaf_blocks, status
2  from dba_indexes i where table_name='MUSE' and partitioned = 'NO'
3  union select index_name, i.partition_name, num_rows, leaf_blocks, status
4  from dba_ind_partitions i where index_name like 'MUSE%';

INDEX_NAME      PARTITION_NAME    NUM_ROWS LEAF_BLOCKS STATUS
--------------- --------------- ---------- ----------- --------
MUSE_CODE_I     CODE_P1            1500000        4135 UNUSABLE
MUSE_CODE_I     CODE_P2            1500000        4177 UNUSABLE
MUSE_ID_I                          3000000        8633 UNUSABLE

Both global indexes are now unusable as a result as they haven’t been maintained on the fly and so have orphaned index entries pointing to the now non-existent table partition. So it was fast but left the global indexes in an unusable state which have to now be rebuilt.

The other option would be to drop the table partition but to also update the global indexes at the same time as follows:

SQL> select n.name, s.value from v$sesstat s, v$statname n where s.statistic# = n.statistic# and (n.name = 'redo size' or n.name = 'db block gets') and s.sid=129;
NAME               VALUE
------------  ----------
db block gets     129615
redo size      103978912

SQL> alter table muse drop partition muse1 update global indexes;

Table altered.

Elapsed: 00:00:13.08

SQL> select n.name, s.value from v$sesstat s, v$statname n where s.statistic# =n.statistic# and (n.name = 'redo size' or n.name = 'db block gets') and s.sid=129;

NAME                VALUE
-------------- ----------
db block gets      185758
redo size       148012132 

We notice this time, the operation has taken considerably longer and has generated many more db block gets (56,143 up from 56) and much more redo  (44,033,220 bytes up from 10,860).  So updating the global indexes on the fly comes at a cost, but at least they remain usable at the end of the operation:

SQL> select index_name, null partition_name, num_rows, s.blocks, leaf_blocks, status from dba_indexes i, dba_segments s where i.index_name = s.segment_name andtable_name='MUSE' and partitioned = 'NO'
2  union select index_name, i.partition_name, num_rows, s.blocks, leaf_blocks, status from dba_ind_partitions i, dba_segments s where i.partition_name = s.partition_name and index_name like 'MUSE%';

INDEX_NAME      PARTITION_NAME    NUM_ROWS     BLOCKS LEAF_BLOCKS STATUS
--------------- --------------- ---------- ---------- ----------- --------
MUSE_CODE_I     CODE_P1            1000000       4224        4135 USABLE
MUSE_CODE_I     CODE_P2            1000000       4352        4177 USABLE
MUSE_ID_I                          2000000       9216        5849 VALID

Having updated the global indexes and having effectively deleted 1/3 of the table with the lowest ID values, if we were to now try and find the current minimum ID value:

SQL> select min(id) from muse;
MIN(ID)
----------
1000001

Execution Plan
----------------------------------------------------------
Plan hash value: 2104594370
----------------------------------------------------------------------------------------
| Id  | Operation                  | Name      | Rows  | Bytes | Cost (%CPU)| Time     |
----------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT           |           |     1 |     6 |     3   (0)| 00:00:01 |
|   1 |  SORT AGGREGATE            |           |     1 |     6 |            |          |
|   2 |   INDEX FULL SCAN (MIN/MAX)| MUSE_ID_I |     1 |     6 |     3   (0)| 00:00:01 |
----------------------------------------------------------------------------------------

Statistics
----------------------------------------------------------

0  recursive calls
0  db block gets
2787  consistent gets
0  physical reads
0  redo size
528  bytes sent via SQL*Net to client
520  bytes received via SQL*Net from client
2  SQL*Net roundtrips to/from client
0  sorts (memory)
0  sorts (disk)
1  rows processed

The CBO is trying to use the index via the Index Full Min/Max Scan to quickly find this minimum ID. However, it keeps hitting leaf blocks with nothing but empty/deleted entries due to dropping the table partition, until it gets through roughly 1/3 of all the index leaf blocks before finally finding the first (and so minimum) non-deleted index value. As such, at 2,787 consistent gets, it’s a relatively expensive operation.

If however, we were to insert a whole bunch of new rows into the table (note these are rows with an ID value greater than existing rows) and then re-run the same query:

SQL> insert into muse select rownum+3000000, mod(rownum,100000), 'DAVID BOWIE'
from dual connect by level <= 1000000;

1000000 rows created.

SQL> commit;

Commit complete.

SQL> select min(id) from muse;

MIN(ID)
----------
1000001

Execution Plan
----------------------------------------------------------

Plan hash value: 2104594370
----------------------------------------------------------------------------------------
| Id  | Operation                  | Name      | Rows  | Bytes | Cost (%CPU)| Time     |
----------------------------------------------------------------------------------------
|   0 | SELECT STATEMENT           |           |     1 |     6 |     3   (0)| 00:00:01 |
|   1 |  SORT AGGREGATE            |           |     1 |     6 |            |          |
|   2 |   INDEX FULL SCAN (MIN/MAX)| MUSE_ID_I |     1 |     6 |     3   (0)| 00:00:01 |
----------------------------------------------------------------------------------------

Statistics
----------------------------------------------------------

0  recursive calls
0  db block gets
161  consistent gets
0  physical reads
0  redo size
528  bytes sent via SQL*Net to client
500  bytes received via SQL*Net from client
2  SQL*Net roundtrips to/from client
0  sorts (memory)
0  sorts (disk)
1  rows processed

We notice that at just 161 consistent gets (reduced from 2,787), the Index Full Min/MAX Scan is much more efficient as most of the previously empty leaf blocks on the “left hand side of the index” have now been recycled due to inserting the new data into the “right hand side of the index”. As such, we now find the minimum ID value via the index much more efficiently.

So that was how things kinda worked in 11g and beforehand. However, with Oracle 12c, things have now changed as we’ll see in the next post …

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