DEVELOPER: PL/SQL Practices
On BULK COLLECT
By Steven Feuerstein
Best practices for knowing your LIMIT and kicking %NOTFOUND
I have started using BULK COLLECT whenever I need to fetch large volumes of data. This has caused me some trouble with my DBA, however. He is complaining that although my programs might be running much faster, they are also consuming way too much memory. He refuses to approve them for a production rollout. What's a programmer to do?
The most important thing to remember when you learn about and start to take advantage of features such as BULK COLLECT is that there is no free lunch. There is almost always a trade-off to be made somewhere. The tradeoff with BULK COLLECT, like so many other performance-enhancing features, is "run faster but consume more memory."
Specifically, memory for collections is stored in the program global area (PGA), not the system global area (SGA). SGA memory is shared by all sessions connected to Oracle Database, but PGA memory is allocated for each session. Thus, if a program requires 5MB of memory to populate a collection and there are 100 simultaneous connections, that program causes the consumption of 500MB of PGA memory, in addition to the memory allocated to the SGA.
Fortunately, PL/SQL makes it easy for developers to control the amount of memory used in a BULK COLLECT operation by using the LIMIT clause.
Suppose I need to retrieve all the rows from the employees table and then perform some compensation analysis on each row. I can use BULK COLLECT as follows:
PROCEDURE process_all_rows IS TYPE employees_aat IS TABLE OF employees%ROWTYPE INDEX BY PLS_INTEGER; l_employees employees_aat; BEGIN SELECT * BULK COLLECT INTO l_employees FROM employees; FOR indx IN 1 .. l_employees.COUNT LOOP analyze_compensation (l_employees(indx)); END LOOP; END process_all_rows;
Very concise, elegant, and efficient code. If, however, my employees table contains tens of thousands of rows, each of which contains hundreds of columns, this program can cause excessive PGA memory consumption.
Consequently, you should avoid this sort of "unlimited" use of BULK COLLECT. Instead, move the SELECT statement into an explicit cursor declaration and then use a simple loop to fetch many, but not all, rows from the table with each execution of the loop body, as shown in Listing 1.
Code Listing 1: Using BULK COLLECT with LIMIT clause
PROCEDURE process_all_rows (limit_in IN PLS_INTEGER DEFAULT 100) IS CURSOR employees_cur IS SELECT * FROM employees; TYPE employees_aat IS TABLE OF employees_cur%ROWTYPE INDEX BY PLS_INTEGER; l_employees employees_aat; BEGIN OPEN employees_cur; LOOP FETCH employees_cur BULK COLLECT INTO l_employees LIMIT limit_in; FOR indx IN 1 .. l_employees.COUNT LOOP analyze_compensation (l_employees(indx)); END LOOP; EXIT WHEN l_employees.COUNT < limit_in; END LOOP; CLOSE employees_cur; END process_all_rows;
The process_all_rows procedure in Listing 1 requests that up to the value of limit_in rows be fetched at a time. PL/SQL will reuse the same limit_in elements in the collection each time the data is fetched and thus also reuse the same memory. Even if my table grows in size, the PGA consumption will remain stable.
How do you decide what number to use in the LIMIT clause? Theoretically, you will want to figure out how much memory you can afford to consume in the PGA and then adjust the limit to be as close to that amount as possible.
From tests I (and others) have performed, however, it appears that you will see roughly the same performance no matter what value you choose for the limit, as long as it is at least 25. The test_diff_limits.sql script, included with the sample code for this column, demonstrates this behavior, using the ALL_SOURCE data dictionary view on an Oracle Database 11g instance. Here are the results I saw (in hundredths of seconds) when fetching all the rows (a total of 470,000):
Elapsed CPU time for limit of 1 = 1839 Elapsed CPU time for limit of 5 = 716 Elapsed CPU time for limit of 25 = 539 Elapsed CPU time for limit of 50 = 545 Elapsed CPU time for limit of 75 = 489 Elapsed CPU time for limit of 100 = 490 Elapsed CPU time for limit of 1000 = 501 Elapsed CPU time for limit of 10000 = 478 Elapsed CPU time for limit of 100000 = 527
Kicking the %NOTFOUND Habit
I was very happy to learn that Oracle Database 10g will automatically optimize my cursor FOR loops to perform at speeds comparable to BULK COLLECT. Unfortunately, my company is still running on Oracle9i Database, so I have started converting my cursor FOR loops to BULK COLLECTs. I have run into a problem: I am using a LIMIT of 100, and my query retrieves a total of 227 rows, but my program processes only 200 of them. [The query is shown in Listing 2.] What am I doing wrong?
Code Listing 2: BULK COLLECT, %NOTFOUND, and missing rows
PROCEDURE process_all_rows
IS
CURSOR table_with_227_rows_cur
IS
SELECT * FROM table_with_227_rows;
TYPE table_with_227_rows_aat IS
TABLE OF table_with_227_rows_cur%ROWTYPE
INDEX BY PLS_INTEGER;
l_table_with_227_rows table_with_227_rows_aat;
BEGIN
OPEN table_with_227_rows_cur;
LOOP
FETCH table_with_227_rows_cur
BULK COLLECT INTO l_table_with_227_rows LIMIT 100;
EXIT WHEN table_with_227_rows_cur%NOTFOUND; /* cause of missing rows */
FOR indx IN 1 .. l_table_with_227_rows.COUNT
LOOP
analyze_compensation (l_table_with_227_rows(indx));
END LOOP;
END LOOP;
CLOSE table_with_227_rows_cur;
END process_all_rows;
You came so close to a completely correct conversion from your cursor FOR loop to BULK COLLECT! Your only mistake was that you didn't give up the habit of using the %NOTFOUND cursor attribute in your EXIT WHEN clause.
The statement
EXIT WHEN table_with_227_rows_cur%NOTFOUND;
makes perfect sense when you are fetching your data one row at a time. With BULK COLLECT, however, that line of code can result in incomplete data processing, precisely as you described.
Let's examine what is happening when you run your program and why those last 27 rows are left out. After opening the cursor and entering the loop, here is what occurs:
1. The fetch statement retrieves rows 1 through 100.
2. table_with_227_rows_cur%NOTFOUND evaluates to FALSE, and the rows are processed.
3. The fetch statement retrieves rows 101 through 200.
4. table_with_227_rows_cur%NOTFOUND evaluates to FALSE, and the rows are processed.
5. The fetch statement retrieves rows 201 through 227.
6. table_with_227_rows_cur%NOTFOUND evaluates to TRUE , and the loop is terminatedwith 27 rows left to process!
2. table_with_227_rows_cur%NOTFOUND evaluates to FALSE, and the rows are processed.
3. The fetch statement retrieves rows 101 through 200.
4. table_with_227_rows_cur%NOTFOUND evaluates to FALSE, and the rows are processed.
5. The fetch statement retrieves rows 201 through 227.
6. table_with_227_rows_cur%NOTFOUND evaluates to TRUE , and the loop is terminatedwith 27 rows left to process!
|
So, to make sure that your query processes all 227 rows, replace this statement:
EXIT WHEN table_with_227_rows_cur%NOTFOUND; with EXIT WHEN l_table_with_227_rows.COUNT = 0;
Generally, you should keep all of the following in mind when working with BULK COLLECT:
- The collection is always filled sequentially, starting from index value 1.
- It is always safe (that is, you will never raise a NO_DATA_FOUND exception) to iterate through a collection from 1 to collection .COUNT when it has been filled with BULK COLLECT.
- The collection is empty when no rows are fetched.
- Always check the contents of the collection (with the COUNT method) to see if there are more rows to process.
- Ignore the values returned by the cursor attributes, especially %NOTFOUND.
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