I have a following table (pseudo DDL):
CREATE TABLE MESSAGE ( MESSAGE_GUID GUID PRIMARY KEY, INSERT_TIME DATETIME ) CREATE INDEX MESSAGE_IE1 ON MESSAGE (INSERT_TIME);
Several clients concurrently insert rows in that table, possibly many times per second. I need to design a "Monitor" application that will:
- Initially, fetch all the rows currently in the table.
- After that, periodically check if there are any new rows inserted and then fetch these rows only.
There may be multiple Monitors concurrently running. All the Monitors need to see all the rows (i.e. when a row is inserted, it must be "detected" by all the currently running Monitors).
This application will be developed for Oracle initially, but we need to keep it portable to every major RDBMS and would like to avoid as much database-specific stuff as possible.
The naive solution would be to simply find the maximal INSERT_TIME in rows selected in step 1 and then...
SELECT * FROM MESSAGE WHERE INSERT_TIME >= :max_insert_time_from_previous_select
...in step 2.
However, I'm worried this might lead to race conditions. Consider the following scenario:
- Transaction A inserts a new row but does not yet commit.
- Transaction B inserts a new row and commits.
- The Monitor selects rows and sees that the maximal INSERT_TIME is the one inserted by B.
- Transaction A commits. At this point, A's INSERT_TIME is actually earlier than the B's (A's INSERT was actually executed before B's, before we even knew who is going to commit first).
- The Monitor selects rows newer than B's INSERT_TIME (as a consequence of step 3). Since A's INSERT_TIME is earlier than B's insert time, A's row is skipped.
So, the row inserted by transaction A is never fetched.
Any ideas how to design the client SQL or even change the database schema (as long as it is mildly portable), so these kinds of concurrency problems are avoided, while still keeping a decent performance?