# 2005 November 30 # # The author disclaims copyright to this source code. In place of # a legal notice, here is a blessing: # # May you do good and not evil. # May you find forgiveness for yourself and forgive others. # May you share freely, never taking more than you give. # #*********************************************************************** # # This file contains test cases focused on the two memory-management APIs, # sqlite3_soft_heap_limit() and sqlite3_release_memory(). # # $Id: malloc5.test,v 1.17 2007/10/03 09:43:55 danielk1977 Exp $ #--------------------------------------------------------------------------- # NOTES ON EXPECTED BEHAVIOUR # #--------------------------------------------------------------------------- set testdir [file dirname $argv0] source $testdir/tester.tcl db close # Only run these tests if memory debugging is turned on. # ifcapable !memdebug { puts "Skipping malloc5 tests: not compiled with -DSQLITE_MEMDEBUG..." finish_test return } # Skip these tests if OMIT_MEMORY_MANAGEMENT was defined at compile time. ifcapable !memorymanage { finish_test return } sqlite3_soft_heap_limit 0 sqlite3 db test.db do_test malloc5-1.1 { # Simplest possible test. Call sqlite3_release_memory when there is exactly # one unused page in a single pager cache. This test case set's the # value of the ::pgalloc variable, which is used in subsequent tests. # # Note: Even though executing this statement on an empty database # modifies 2 pages (the root of sqlite_master and the new root page), # the sqlite_master root (page 1) is never freed because the btree layer # retains a reference to it for the entire transaction. execsql { PRAGMA auto_vacuum=OFF; BEGIN; CREATE TABLE abc(a, b, c); } set ::pgalloc [sqlite3_release_memory] expr $::pgalloc > 0 } {1} do_test malloc5-1.2 { # Test that the transaction started in the above test is still active. # Because the page freed had been written to, freeing it required a # journal sync and exclusive lock on the database file. Test the file # appears to be locked. sqlite3 db2 test.db catchsql { SELECT * FROM abc; } db2 } {1 {database is locked}} do_test malloc5-1.3 { # Again call [sqlite3_release_memory] when there is exactly one unused page # in the cache. The same amount of memory is required, but no journal-sync # or exclusive lock should be established. execsql { COMMIT; BEGIN; SELECT * FROM abc; } sqlite3_release_memory } $::pgalloc do_test malloc5-1.4 { # Database should not be locked this time. catchsql { SELECT * FROM abc; } db2 } {0 {}} do_test malloc5-1.5 { # Manipulate the cache so that it contains two unused pages. One requires # a journal-sync to free, the other does not. db2 close execsql { SELECT * FROM abc; CREATE TABLE def(d, e, f); } sqlite3_release_memory 500 } $::pgalloc do_test malloc5-1.6 { # Database should not be locked this time. The above test case only # requested 500 bytes of memory, which can be obtained by freeing the page # that does not require an fsync(). sqlite3 db2 test.db catchsql { SELECT * FROM abc; } db2 } {0 {}} do_test malloc5-1.7 { # Release another 500 bytes of memory. This time we require a sync(), # so the database file will be locked afterwards. db2 close sqlite3_release_memory 500 } $::pgalloc do_test malloc5-1.8 { sqlite3 db2 test.db catchsql { SELECT * FROM abc; } db2 } {1 {database is locked}} do_test malloc5-1.9 { execsql { COMMIT; } } {} do_test malloc5-2.1 { # Put some data in tables abc and def. Both tables are still wholly # contained within their root pages. execsql { INSERT INTO abc VALUES(1, 2, 3); INSERT INTO abc VALUES(4, 5, 6); INSERT INTO def VALUES(7, 8, 9); INSERT INTO def VALUES(10,11,12); } } {} do_test malloc5-2.2 { # Load the root-page for table def into the cache. Then query table abc. # Halfway through the query call sqlite3_release_memory(). The goal of this # test is to make sure we don't free pages that are in use (specifically, # the root of table abc). set nRelease 0 execsql { BEGIN; SELECT * FROM def; } set data [list] db eval {SELECT * FROM abc} { incr nRelease [sqlite3_release_memory] lappend data $a $b $c } execsql { COMMIT; } list $nRelease $data } [list $pgalloc [list 1 2 3 4 5 6]] do_test malloc5-3.1 { # Simple test to show that if two pagers are opened from within this # thread, memory is freed from both when sqlite3_release_memory() is # called. execsql { BEGIN; SELECT * FROM abc; } execsql { SELECT * FROM sqlite_master; BEGIN; SELECT * FROM def; } db2 sqlite3_release_memory } [expr $::pgalloc * 2] do_test malloc5-3.2 { concat \ [execsql {SELECT * FROM abc; COMMIT}] \ [execsql {SELECT * FROM def; COMMIT} db2] } {1 2 3 4 5 6 7 8 9 10 11 12} db2 close puts "Highwater mark: [sqlite3_memory_highwater]" # The following two test cases each execute a transaction in which # 10000 rows are inserted into table abc. The first test case is used # to ensure that more than 1MB of dynamic memory is used to perform # the transaction. # # The second test case sets the "soft-heap-limit" to 100,000 bytes (0.1 MB) # and tests to see that this limit is not exceeded at any point during # transaction execution. # # Before executing malloc5-4.* we save the value of the current soft heap # limit in variable ::soft_limit. The original value is restored after # running the tests. # set ::soft_limit [sqlite3_soft_heap_limit -1] execsql {PRAGMA cache_size=2000} do_test malloc5-4.1 { execsql {BEGIN;} execsql {DELETE FROM abc;} for {set i 0} {$i < 10000} {incr i} { execsql "INSERT INTO abc VALUES($i, $i, '[string repeat X 100]');" } execsql {COMMIT;} set nMaxBytes [sqlite3_memory_highwater 1] puts -nonewline " (Highwater mark: $nMaxBytes) " expr $nMaxBytes > 1000000 } {1} do_test malloc5-4.2 { sqlite3_release_memory sqlite3_soft_heap_limit 100000 sqlite3_memory_highwater 1 execsql {BEGIN;} for {set i 0} {$i < 10000} {incr i} { execsql "INSERT INTO abc VALUES($i, $i, '[string repeat X 100]');" } execsql {COMMIT;} set nMaxBytes [sqlite3_memory_highwater 1] puts -nonewline " (Highwater mark: $nMaxBytes) " # We used to test ($nMaxBytes<100000), because the soft-heap-limit is # 100000 bytes. But if an allocation that will exceed the # soft-heap-limit is requested from within the only pager instance in # the system, then there is no way to free memory and the limit has to # be exceeded. An exception is memory allocated to store actual page # data (the code contains a special case for this). # # This is not a problem because all allocations apart from those # used to store cached page data are both small and transient. # # Summary: the actual high-water mark for memory usage may be slightly # higher than the soft-heap-limit. The specific allocations that cause # the problem are the calls to sqlite3_malloc() inserted into selected # sqlite3OsXXX() functions in test builds. # expr $nMaxBytes <= 100100 } {1} do_test malloc5-4.3 { # Check that the content of table abc is at least roughly as expected. execsql { SELECT count(*), sum(a), sum(b) FROM abc; } } [list 20000 [expr int(20000.0 * 4999.5)] [expr int(20000.0 * 4999.5)]] # Restore the soft heap limit. sqlite3_soft_heap_limit $::soft_limit # Test that there are no problems calling sqlite3_release_memory when # there are open in-memory databases. # # At one point these tests would cause a seg-fault. # do_test malloc5-5.1 { db close sqlite3 db :memory: execsql { BEGIN; CREATE TABLE abc(a, b, c); INSERT INTO abc VALUES('abcdefghi', 1234567890, NULL); INSERT INTO abc SELECT * FROM abc; INSERT INTO abc SELECT * FROM abc; INSERT INTO abc SELECT * FROM abc; INSERT INTO abc SELECT * FROM abc; INSERT INTO abc SELECT * FROM abc; INSERT INTO abc SELECT * FROM abc; INSERT INTO abc SELECT * FROM abc; } sqlite3_release_memory } 0 do_test malloc5-5.2 { sqlite3_soft_heap_limit 5000 execsql { COMMIT; PRAGMA temp_store = memory; SELECT * FROM abc ORDER BY a; } expr 1 } {1} sqlite3_soft_heap_limit $::soft_limit #------------------------------------------------------------------------- # The following test cases (malloc5-6.*) test the new global LRU list # used to determine the pages to recycle when sqlite3_release_memory is # called and there is more than one pager open. # proc nPage {db} { set bt [btree_from_db $db] array set stats [btree_pager_stats $bt] set stats(page) } db close file delete -force test.db test.db-journal test2.db test2.db-journal # This block of test-cases (malloc5-6.1.*) prepares two database files # for the subsequent tests. do_test malloc5-6.1.1 { sqlite3 db test.db execsql { PRAGMA page_size=1024; PRAGMA default_cache_size=10; BEGIN; CREATE TABLE abc(a PRIMARY KEY, b, c); INSERT INTO abc VALUES(randstr(50,50), randstr(75,75), randstr(100,100)); INSERT INTO abc SELECT randstr(50,50), randstr(75,75), randstr(100,100) FROM abc; INSERT INTO abc SELECT randstr(50,50), randstr(75,75), randstr(100,100) FROM abc; INSERT INTO abc SELECT randstr(50,50), randstr(75,75), randstr(100,100) FROM abc; INSERT INTO abc SELECT randstr(50,50), randstr(75,75), randstr(100,100) FROM abc; INSERT INTO abc SELECT randstr(50,50), randstr(75,75), randstr(100,100) FROM abc; INSERT INTO abc SELECT randstr(50,50), randstr(75,75), randstr(100,100) FROM abc; COMMIT; } copy_file test.db test2.db sqlite3 db2 test2.db list \ [expr ([file size test.db]/1024)>20] [expr ([file size test2.db]/1024)>20] } {1 1} do_test malloc5-6.1.2 { list [execsql {PRAGMA cache_size}] [execsql {PRAGMA cache_size} db2] } {10 10} do_test malloc5-6.2.1 { execsql { SELECT * FROM abc } db2 execsql {SELECT * FROM abc} db list [nPage db] [nPage db2] } {10 10} do_test malloc5-6.2.2 { # If we now try to reclaim some memory, it should come from the db2 cache. sqlite3_release_memory 3000 list [nPage db] [nPage db2] } {10 7} do_test malloc5-6.2.3 { # Access the db2 cache again, so that all the db2 pages have been used # more recently than all the db pages. Then try to reclaim 3000 bytes. # This time, 3 pages should be pulled from the db cache. execsql { SELECT * FROM abc } db2 sqlite3_release_memory 3000 list [nPage db] [nPage db2] } {7 10} do_test malloc5-6.3.1 { # Now open a transaction and update 2 pages in the db2 cache. Then # do a SELECT on the db cache so that all the db pages are more recently # used than the db2 pages. When we try to free memory, SQLite should # free the non-dirty db2 pages, then the db pages, then finally use # sync() to free up the dirty db2 pages. The only page that cannot be # freed is page1 of db2. Because there is an open transaction, the # btree layer holds a reference to page 1 in the db2 cache. execsql { BEGIN; UPDATE abc SET c = randstr(100,100) WHERE rowid = 1 OR rowid = (SELECT max(rowid) FROM abc); } db2 execsql { SELECT * FROM abc } db list [nPage db] [nPage db2] } {10 10} do_test malloc5-6.3.2 { # Try to release 7700 bytes. This should release all the # non-dirty pages held by db2. sqlite3_release_memory [expr 7*1100] list [nPage db] [nPage db2] } {10 3} do_test malloc5-6.3.3 { # Try to release another 1000 bytes. This should come fromt the db # cache, since all three pages held by db2 are either in-use or diry. sqlite3_release_memory 1000 list [nPage db] [nPage db2] } {9 3} do_test malloc5-6.3.4 { # Now release 9900 more (about 9 pages worth). This should expunge # the rest of the db cache. But the db2 cache remains intact, because # SQLite tries to avoid calling sync(). sqlite3_release_memory 9900 list [nPage db] [nPage db2] } {0 3} do_test malloc5-6.3.5 { # But if we are really insistent, SQLite will consent to call sync() # if there is no other option. sqlite3_release_memory 1000 list [nPage db] [nPage db2] } {0 2} do_test malloc5-6.3.6 { # The referenced page (page 1 of the db2 cache) will not be freed no # matter how much memory we ask for: sqlite3_release_memory 31459 list [nPage db] [nPage db2] } {0 1} db2 close sqlite3_soft_heap_limit $::soft_limit finish_test catch {db close}