third_party/perfetto/buildtools/sqlite_src/test/malloc5.test - cobalt - Git at Google

 # 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().
 #
 # Prior to version 3.6.2, calling sqlite3_release_memory() or exceeding
 # the configured soft heap limit could cause sqlite to upgrade database
 # locks and flush dirty pages to the file system. As of 3.6.2, this is
 # no longer the case. In version 3.6.2, sqlite3_release_memory() only
 # reclaims clean pages. This test file has been updated accordingly.
 #
 # $Id: malloc5.test,v 1.22 2009/04/11 19:09:54 drh Exp $

 set testdir [file dirname $argv0]
 source $testdir/tester.tcl
 source $testdir/malloc_common.tcl
 db close

 # Only run these tests if memory debugging is turned on.
 #
 if {!$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
 }

 # The sizes of memory allocations from system malloc() might vary,
 # depending on the memory allocator algorithms used.  The following
 # routine is designed to support answers that fall within a range
 # of values while also supplying easy-to-understand "expected" values
 # when errors occur.
 #
 proc value_in_range {target x args} {
   set v [lindex $args 0]
   if {$v!=""} {
     if {$v<$target*$x} {return $v}
     if {$v>$target/$x} {return $v}
   }
   return "number between [expr {int($target*$x)}] and [expr {int($target/$x)}]"
 }
 set mrange 0.98   ;#  plus or minus 2%

 test_set_config_pagecache 0 100

 sqlite3_soft_heap_limit 0
 sqlite3 db test.db
 # db eval {PRAGMA cache_size=1}

 do_test malloc5-1.1 {
   # Simplest possible test. Call sqlite3_release_memory when there is exactly
   # one unused page in a single pager cache. The page cannot be freed, as
   # it is dirty. So sqlite3_release_memory() returns 0.
   #
   execsql {
     PRAGMA auto_vacuum=OFF;
     BEGIN;
     CREATE TABLE abc(a, b, c);
   }
   sqlite3_release_memory
 } {0}

 do_test malloc5-1.2 {
   # Test that the transaction started in the above test is still active.
   # The lock on the database file should not have been upgraded (this was
   # not the case before version 3.6.2).
   #
   sqlite3 db2 test.db
   execsql {PRAGMA cache_size=2; SELECT * FROM sqlite_master } db2
 } {}
 do_test malloc5-1.3 {
   # Call [sqlite3_release_memory] when there is exactly one unused page
   # in the cache belonging to db2.
   #
   set ::pgalloc [sqlite3_release_memory]
   value_in_range 1288 0.75
 } [value_in_range 1288 0.75]

 do_test malloc5-1.4 {
   # Commit the transaction and open a new one. Read 1 page into the cache.
   # Because the page is not dirty, it is eligible for collection even
   # before the transaction is concluded.
   #
   execsql {
     COMMIT;
     BEGIN;
     SELECT * FROM abc;
   }
   value_in_range $::pgalloc $::mrange [sqlite3_release_memory]
 } [value_in_range $::pgalloc $::mrange]

 do_test malloc5-1.5 {
   # Conclude the transaction opened in the previous [do_test] block. This
   # causes another page (page 1) to become eligible for recycling.
   #
   execsql { COMMIT }
   value_in_range $::pgalloc $::mrange [sqlite3_release_memory]
 } [value_in_range $::pgalloc $::mrange]

 do_test malloc5-1.6 {
   # Manipulate the cache so that it contains two unused pages. One requires
   # a journal-sync to free, the other does not.
   db2 close
   execsql {
     BEGIN;
     CREATE TABLE def(d, e, f);
     SELECT * FROM abc;
   }
   value_in_range $::pgalloc $::mrange [sqlite3_release_memory 500]
 } [value_in_range $::pgalloc $::mrange]
 do_test malloc5-1.7 {
   # Database should not be locked this time.
   sqlite3 db2 test.db
   catchsql { SELECT * FROM abc } db2
 } {0 {}}
 do_test malloc5-1.8 {
   # Try to release another block of memory. This will fail as the only
   # pages currently in the cache are dirty (page 3) or pinned (page 1).
   db2 close
   sqlite3_release_memory 500
 } 0
 do_test malloc5-1.8 {
   # Database is still not locked.
   #
   sqlite3 db2 test.db
   catchsql { SELECT * FROM abc } db2
 } {0 {}}
 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).
   sqlite3_release_memory
   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;
   }
   value_in_range $::pgalloc $::mrange $nRelease
 } [value_in_range $::pgalloc $::mrange]
 do_test malloc5-2.2.1 {
   set data
 } {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
   value_in_range [expr $::pgalloc*2] 0.99 [sqlite3_release_memory]
 } [value_in_range [expr $::pgalloc * 2] 0.99]
 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;}
   db cache flush
   sqlite3_release_memory
   sqlite3_memory_highwater 1
   execsql {SELECT * FROM abc}
   set nMaxBytes [sqlite3_memory_highwater 1]
   puts -nonewline " (Highwater mark: $nMaxBytes) "
   expr $nMaxBytes > 1000000
 } {1}
 do_test malloc5-4.2 {
   db eval {PRAGMA cache_size=1}
   db cache flush
   sqlite3_release_memory
   sqlite3_soft_heap_limit 200000
   sqlite3_memory_highwater 1
   execsql {SELECT * FROM abc}
   set nMaxBytes [sqlite3_memory_highwater 1]
   puts -nonewline " (Highwater mark: $nMaxBytes) "
   expr $nMaxBytes <= 210000
 } {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 10000 [expr int(10000.0 * 4999.5)] [expr int(10000.0 * 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
 forcedelete 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=2;
   }
   execsql {
     PRAGMA temp_store = memory;
     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;
   }
   forcecopy test.db test2.db
   sqlite3 db2 test2.db
   db2 eval {PRAGMA cache_size=2}
   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]
 } {2 2}

 do_test malloc5-6.2.1 {
   execsql {SELECT * FROM abc} db2
   execsql {SELECT * FROM abc} db
   expr [nPage db] + [nPage db2]
 } {4}

 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
   expr [nPage db] + [nPage db2]
 } {1}
 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
   expr [nPage db] + [nPage db2]
 } {0}

 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.
   #
   # UPDATE: No longer. As release_memory() does not cause a sync()
   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
   expr [nPage db] + [nPage db2]
 } {4}
 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*1132]
   list [nPage db] [nPage db2]
 } {0 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]
 } {0 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().
   if {$::tcl_platform(wordSize)==8} {
     sqlite3_release_memory 10500
   } else {
     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. UPDATE: As of 3.6.2, SQLite will not
   # call sync() in this scenario. So no further memory can be reclaimed.
   sqlite3_release_memory 1000
   list [nPage db] [nPage db2]
 } {0 3}
 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 3}

 db2 close

 sqlite3_soft_heap_limit $::soft_limit
 test_restore_config_pagecache
 finish_test
 catch {db close}
	# 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().
	#
	# Prior to version 3.6.2, calling sqlite3_release_memory() or exceeding
	# the configured soft heap limit could cause sqlite to upgrade database
	# locks and flush dirty pages to the file system. As of 3.6.2, this is
	# no longer the case. In version 3.6.2, sqlite3_release_memory() only
	# reclaims clean pages. This test file has been updated accordingly.
	#
	# $Id: malloc5.test,v 1.22 2009/04/11 19:09:54 drh Exp $

	set testdir [file dirname $argv0]
	source $testdir/tester.tcl
	source $testdir/malloc_common.tcl
	db close

	# Only run these tests if memory debugging is turned on.
	#
	if {!$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
	}

	# The sizes of memory allocations from system malloc() might vary,
	# depending on the memory allocator algorithms used. The following
	# routine is designed to support answers that fall within a range
	# of values while also supplying easy-to-understand "expected" values
	# when errors occur.
	#
	proc value_in_range {target x args} {
	set v [lindex $args 0]
	if {$v!=""} {
	if {$v<$target*$x} {return $v}
	if {$v>$target/$x} {return $v}
	}
	return "number between [expr {int($target*$x)}] and [expr {int($target/$x)}]"
	}
	set mrange 0.98 ;# plus or minus 2%

	test_set_config_pagecache 0 100

	sqlite3_soft_heap_limit 0
	sqlite3 db test.db
	# db eval {PRAGMA cache_size=1}

	do_test malloc5-1.1 {
	# Simplest possible test. Call sqlite3_release_memory when there is exactly
	# one unused page in a single pager cache. The page cannot be freed, as
	# it is dirty. So sqlite3_release_memory() returns 0.
	#
	execsql {
	PRAGMA auto_vacuum=OFF;
	BEGIN;
	CREATE TABLE abc(a, b, c);
	}
	sqlite3_release_memory
	} {0}

	do_test malloc5-1.2 {
	# Test that the transaction started in the above test is still active.
	# The lock on the database file should not have been upgraded (this was
	# not the case before version 3.6.2).
	#
	sqlite3 db2 test.db
	execsql {PRAGMA cache_size=2; SELECT * FROM sqlite_master } db2
	} {}
	do_test malloc5-1.3 {
	# Call [sqlite3_release_memory] when there is exactly one unused page
	# in the cache belonging to db2.
	#
	set ::pgalloc [sqlite3_release_memory]
	value_in_range 1288 0.75
	} [value_in_range 1288 0.75]

	do_test malloc5-1.4 {
	# Commit the transaction and open a new one. Read 1 page into the cache.
	# Because the page is not dirty, it is eligible for collection even
	# before the transaction is concluded.
	#
	execsql {
	COMMIT;
	BEGIN;
	SELECT * FROM abc;
	}
	value_in_range $::pgalloc $::mrange [sqlite3_release_memory]
	} [value_in_range $::pgalloc $::mrange]

	do_test malloc5-1.5 {
	# Conclude the transaction opened in the previous [do_test] block. This
	# causes another page (page 1) to become eligible for recycling.
	#
	execsql { COMMIT }
	value_in_range $::pgalloc $::mrange [sqlite3_release_memory]
	} [value_in_range $::pgalloc $::mrange]

	do_test malloc5-1.6 {
	# Manipulate the cache so that it contains two unused pages. One requires
	# a journal-sync to free, the other does not.
	db2 close
	execsql {
	BEGIN;
	CREATE TABLE def(d, e, f);
	SELECT * FROM abc;
	}
	value_in_range $::pgalloc $::mrange [sqlite3_release_memory 500]
	} [value_in_range $::pgalloc $::mrange]
	do_test malloc5-1.7 {
	# Database should not be locked this time.
	sqlite3 db2 test.db
	catchsql { SELECT * FROM abc } db2
	} {0 {}}
	do_test malloc5-1.8 {
	# Try to release another block of memory. This will fail as the only
	# pages currently in the cache are dirty (page 3) or pinned (page 1).
	db2 close
	sqlite3_release_memory 500
	} 0
	do_test malloc5-1.8 {
	# Database is still not locked.
	#
	sqlite3 db2 test.db
	catchsql { SELECT * FROM abc } db2
	} {0 {}}
	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).
	sqlite3_release_memory
	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;
	}
	value_in_range $::pgalloc $::mrange $nRelease
	} [value_in_range $::pgalloc $::mrange]
	do_test malloc5-2.2.1 {
	set data
	} {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
	value_in_range [expr $::pgalloc*2] 0.99 [sqlite3_release_memory]
	} [value_in_range [expr $::pgalloc * 2] 0.99]
	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;}
	db cache flush
	sqlite3_release_memory
	sqlite3_memory_highwater 1
	execsql {SELECT * FROM abc}
	set nMaxBytes [sqlite3_memory_highwater 1]
	puts -nonewline " (Highwater mark: $nMaxBytes) "
	expr $nMaxBytes > 1000000
	} {1}
	do_test malloc5-4.2 {
	db eval {PRAGMA cache_size=1}
	db cache flush
	sqlite3_release_memory
	sqlite3_soft_heap_limit 200000
	sqlite3_memory_highwater 1
	execsql {SELECT * FROM abc}
	set nMaxBytes [sqlite3_memory_highwater 1]
	puts -nonewline " (Highwater mark: $nMaxBytes) "
	expr $nMaxBytes <= 210000
	} {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 10000 [expr int(10000.0 * 4999.5)] [expr int(10000.0 * 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
	forcedelete 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=2;
	}
	execsql {
	PRAGMA temp_store = memory;
	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;
	}
	forcecopy test.db test2.db
	sqlite3 db2 test2.db
	db2 eval {PRAGMA cache_size=2}
	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]
	} {2 2}

	do_test malloc5-6.2.1 {
	execsql {SELECT * FROM abc} db2
	execsql {SELECT * FROM abc} db
	expr [nPage db] + [nPage db2]
	} {4}

	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
	expr [nPage db] + [nPage db2]
	} {1}
	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
	expr [nPage db] + [nPage db2]
	} {0}

	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.
	#
	# UPDATE: No longer. As release_memory() does not cause a sync()
	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
	expr [nPage db] + [nPage db2]
	} {4}
	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*1132]
	list [nPage db] [nPage db2]
	} {0 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]
	} {0 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().
	if {$::tcl_platform(wordSize)==8} {
	sqlite3_release_memory 10500
	} else {
	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. UPDATE: As of 3.6.2, SQLite will not
	# call sync() in this scenario. So no further memory can be reclaimed.
	sqlite3_release_memory 1000
	list [nPage db] [nPage db2]
	} {0 3}
	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 3}

	db2 close

	sqlite3_soft_heap_limit $::soft_limit
	test_restore_config_pagecache
	finish_test
	catch {db close}