third_party/sqlite/src/test/lock.test - cobalt - Git at Google

 # 2001 September 15
 #
 # 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 implements regression tests for SQLite library.  The
 # focus of this script is database locks.
 #
 # $Id: lock.test,v 1.40 2009/06/16 17:49:36 drh Exp $


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

 # Create an alternative connection to the database
 #
 do_test lock-1.0 {
   # Give a complex pathname to stress the path simplification logic in
   # the vxworks driver and in test_async.
   file mkdir tempdir/t1/t2
   sqlite3 db2 ./tempdir/../tempdir/t1/.//t2/../../..//test.db
   set dummy {}
 } {}
 do_test lock-1.1 {
   execsql {SELECT name FROM sqlite_master WHERE type='table' ORDER BY name}
 } {}
 do_test lock-1.2 {
   execsql {SELECT name FROM sqlite_master WHERE type='table' ORDER BY name} db2
 } {}
 do_test lock-1.3 {
   execsql {CREATE TABLE t1(a int, b int)}
   execsql {SELECT name FROM sqlite_master WHERE type='table' ORDER BY name}
 } {t1}
 do_test lock-1.5 {
   catchsql {
      SELECT name FROM sqlite_master WHERE type='table' ORDER BY name
   } db2
 } {0 t1}

 do_test lock-1.6 {
   execsql {INSERT INTO t1 VALUES(1,2)}
   execsql {SELECT * FROM t1}
 } {1 2}
 # Update: The schema is now brought up to date by test lock-1.5.
 # do_test lock-1.7.1 {
 #   catchsql {SELECT * FROM t1} db2
 # } {1 {no such table: t1}}
 do_test lock-1.7.2 {
   catchsql {SELECT * FROM t1} db2
 } {0 {1 2}}
 do_test lock-1.8 {
   execsql {UPDATE t1 SET a=b, b=a} db2
   execsql {SELECT * FROM t1} db2
 } {2 1}
 do_test lock-1.9 {
   execsql {SELECT * FROM t1}
 } {2 1}
 do_test lock-1.10 {
   execsql {BEGIN TRANSACTION}
   execsql {UPDATE t1 SET a = 0 WHERE 0}
   execsql {SELECT * FROM t1}
 } {2 1}
 do_test lock-1.11 {
   catchsql {SELECT * FROM t1} db2
 } {0 {2 1}}
 do_test lock-1.12 {
   execsql {ROLLBACK}
   catchsql {SELECT * FROM t1}
 } {0 {2 1}}

 do_test lock-1.13 {
   execsql {CREATE TABLE t2(x int, y int)}
   execsql {INSERT INTO t2 VALUES(8,9)}
   execsql {SELECT * FROM t2}
 } {8 9}
 do_test lock-1.14.1 {
   catchsql {SELECT * FROM t2} db2
 } {0 {8 9}}
 do_test lock-1.14.2 {
   catchsql {SELECT * FROM t1} db2
 } {0 {2 1}}
 do_test lock-1.15 {
   catchsql {SELECT * FROM t2} db2
 } {0 {8 9}}

 do_test lock-1.16 {
   db eval {SELECT * FROM t1} qv {
     set x [db eval {SELECT * FROM t1}]
   }
   set x
 } {2 1}
 do_test lock-1.17 {
   db eval {SELECT * FROM t1} qv {
     set x [db eval {SELECT * FROM t2}]
   }
   set x
 } {8 9}

 # You cannot UPDATE a table from within the callback of a SELECT
 # on that same table because the SELECT has the table locked.
 #
 # 2006-08-16:  Reads no longer block writes within the same
 # database connection.
 #
 #do_test lock-1.18 {
 #  db eval {SELECT * FROM t1} qv {
 #    set r [catch {db eval {UPDATE t1 SET a=b, b=a}} msg]
 #    lappend r $msg
 #  }
 #  set r
 #} {1 {database table is locked}}

 # But you can UPDATE a different table from the one that is used in
 # the SELECT.
 #
 do_test lock-1.19 {
   db eval {SELECT * FROM t1} qv {
     set r [catch {db eval {UPDATE t2 SET x=y, y=x}} msg]
     lappend r $msg
   }
   set r
 } {0 {}}
 do_test lock-1.20 {
   execsql {SELECT * FROM t2}
 } {9 8}

 # It is possible to do a SELECT of the same table within the
 # callback of another SELECT on that same table because two
 # or more read-only cursors can be open at once.
 #
 do_test lock-1.21 {
   db eval {SELECT * FROM t1} qv {
     set r [catch {db eval {SELECT a FROM t1}} msg]
     lappend r $msg
   }
   set r
 } {0 2}

 # Under UNIX you can do two SELECTs at once with different database
 # connections, because UNIX supports reader/writer locks.  Under windows,
 # this is not possible.
 #
 if {$::tcl_platform(platform)=="unix"} {
   do_test lock-1.22 {
     db eval {SELECT * FROM t1} qv {
       set r [catch {db2 eval {SELECT a FROM t1}} msg]
       lappend r $msg
     }
     set r
   } {0 2}
 }
 integrity_check lock-1.23

 # If one thread has a transaction another thread cannot start
 # a transaction.  -> Not true in version 3.0.  But if one thread
 # as a RESERVED lock another thread cannot acquire one.
 #
 do_test lock-2.1 {
   execsql {BEGIN TRANSACTION}
   execsql {UPDATE t1 SET a = 0 WHERE 0}
   execsql {BEGIN TRANSACTION} db2
   set r [catch {execsql {UPDATE t1 SET a = 0 WHERE 0} db2} msg]
   execsql {ROLLBACK} db2
   lappend r $msg
 } {1 {database is locked}}

 # A thread can read when another has a RESERVED lock.
 #
 do_test lock-2.2 {
   catchsql {SELECT * FROM t2} db2
 } {0 {9 8}}

 # If the other thread (the one that does not hold the transaction with
 # a RESERVED lock) tries to get a RESERVED lock, we do get a busy callback
 # as long as we were not orginally holding a READ lock.
 #
 do_test lock-2.3.1 {
   proc callback {count} {
     set ::callback_value $count
     break
   }
   set ::callback_value {}
   db2 busy callback
   # db2 does not hold a lock so we should get a busy callback here
   set r [catch {execsql {UPDATE t1 SET a=b, b=a} db2} msg]
   lappend r $msg
   lappend r $::callback_value
 } {1 {database is locked} 0}
 do_test lock-2.3.2 {
   set ::callback_value {}
   execsql {BEGIN; SELECT rowid FROM sqlite_master LIMIT 1} db2
   # This time db2 does hold a read lock.  No busy callback this time.
   set r [catch {execsql {UPDATE t1 SET a=b, b=a} db2} msg]
   lappend r $msg
   lappend r $::callback_value
 } {1 {database is locked} {}}
 catch {execsql {ROLLBACK} db2}
 do_test lock-2.4.1 {
   proc callback {count} {
     lappend ::callback_value $count
     if {$count>4} break
   }
   set ::callback_value {}
   db2 busy callback
   # We get a busy callback because db2 is not holding a lock
   set r [catch {execsql {UPDATE t1 SET a=b, b=a} db2} msg]
   lappend r $msg
   lappend r $::callback_value
 } {1 {database is locked} {0 1 2 3 4 5}}
 do_test lock-2.4.2 {
   proc callback {count} {
     lappend ::callback_value $count
     if {$count>4} break
   }
   set ::callback_value {}
   db2 busy callback
   execsql {BEGIN; SELECT rowid FROM sqlite_master LIMIT 1} db2
   # No busy callback this time because we are holding a lock
   set r [catch {execsql {UPDATE t1 SET a=b, b=a} db2} msg]
   lappend r $msg
   lappend r $::callback_value
 } {1 {database is locked} {}}
 catch {execsql {ROLLBACK} db2}
 do_test lock-2.5 {
   proc callback {count} {
     lappend ::callback_value $count
     if {$count>4} break
   }
   set ::callback_value {}
   db2 busy callback
   set r [catch {execsql {SELECT * FROM t1} db2} msg]
   lappend r $msg
   lappend r $::callback_value
 } {0 {2 1} {}}
 execsql {ROLLBACK}

 # Test the built-in busy timeout handler
 #
 do_test lock-2.8 {
   db2 timeout 400
   execsql BEGIN
   execsql {UPDATE t1 SET a = 0 WHERE 0}
   catchsql {BEGIN EXCLUSIVE;} db2
 } {1 {database is locked}}
 do_test lock-2.9 {
   db2 timeout 0
   execsql COMMIT
 } {}
 integrity_check lock-2.10

 # Try to start two transactions in a row
 #
 do_test lock-3.1 {
   execsql {BEGIN TRANSACTION}
   set r [catch {execsql {BEGIN TRANSACTION}} msg]
   execsql {ROLLBACK}
   lappend r $msg
 } {1 {cannot start a transaction within a transaction}}
 integrity_check lock-3.2

 # Make sure the busy handler and error messages work when
 # opening a new pointer to the database while another pointer
 # has the database locked.
 #
 do_test lock-4.1 {
   db2 close
   catch {db eval ROLLBACK}
   db eval BEGIN
   db eval {UPDATE t1 SET a=0 WHERE 0}
   sqlite3 db2 ./test.db
   catchsql {UPDATE t1 SET a=0} db2
 } {1 {database is locked}}
 do_test lock-4.2 {
   set ::callback_value {}
   set rc [catch {db2 eval {UPDATE t1 SET a=0}} msg]
   lappend rc $msg $::callback_value
 } {1 {database is locked} {}}
 do_test lock-4.3 {
   proc callback {count} {
     lappend ::callback_value $count
     if {$count>4} break
   }
   db2 busy callback
   set rc [catch {db2 eval {UPDATE t1 SET a=0}} msg]
   lappend rc $msg $::callback_value
 } {1 {database is locked} {0 1 2 3 4 5}}
 execsql {ROLLBACK}

 # When one thread is writing, other threads cannot read.  Except if the
 # writing thread is writing to its temporary tables, the other threads
 # can still read.  -> Not so in 3.0.  One thread can read while another
 # holds a RESERVED lock.
 #
 proc tx_exec {sql} {
   db2 eval $sql
 }
 do_test lock-5.1 {
   execsql {
     SELECT * FROM t1
   }
 } {2 1}
 do_test lock-5.2 {
   db function tx_exec tx_exec
   catchsql {
     INSERT INTO t1(a,b) SELECT 3, tx_exec('SELECT y FROM t2 LIMIT 1');
   }
 } {0 {}}

 ifcapable tempdb {
   do_test lock-5.3 {
     execsql {
       CREATE TEMP TABLE t3(x);
       SELECT * FROM t3;
     }
   } {}
   do_test lock-5.4 {
     catchsql {
       INSERT INTO t3 SELECT tx_exec('SELECT y FROM t2 LIMIT 1');
     }
   } {0 {}}
   do_test lock-5.5 {
     execsql {
       SELECT * FROM t3;
     }
   } {8}
   do_test lock-5.6 {
     catchsql {
       UPDATE t1 SET a=tx_exec('SELECT x FROM t2');
     }
   } {0 {}}
   do_test lock-5.7 {
     execsql {
       SELECT * FROM t1;
     }
   } {9 1 9 8}
   do_test lock-5.8 {
     catchsql {
       UPDATE t3 SET x=tx_exec('SELECT x FROM t2');
     }
   } {0 {}}
   do_test lock-5.9 {
     execsql {
       SELECT * FROM t3;
     }
   } {9}
 }

 do_test lock-6.1 {
   execsql {
     CREATE TABLE t4(a PRIMARY KEY, b);
     INSERT INTO t4 VALUES(1, 'one');
     INSERT INTO t4 VALUES(2, 'two');
     INSERT INTO t4 VALUES(3, 'three');
   }

   set STMT [sqlite3_prepare $DB "SELECT * FROM sqlite_master" -1 TAIL]
   sqlite3_step $STMT

   execsql { DELETE FROM t4 }
   execsql { SELECT * FROM sqlite_master } db2
   execsql { SELECT * FROM t4 } db2
 } {}

 do_test lock-6.2 {
   execsql {
     BEGIN;
     INSERT INTO t4 VALUES(1, 'one');
     INSERT INTO t4 VALUES(2, 'two');
     INSERT INTO t4 VALUES(3, 'three');
     COMMIT;
   }

   execsql { SELECT * FROM t4 } db2
 } {1 one 2 two 3 three}

 do_test lock-6.3 {
   execsql { SELECT a FROM t4 ORDER BY a } db2
 } {1 2 3}

 do_test lock-6.4 {
   execsql { PRAGMA integrity_check } db2
 } {ok}

 do_test lock-6.5 {
   sqlite3_finalize $STMT
 } {SQLITE_OK}

 # At one point the following set of conditions would cause SQLite to
 # retain a RESERVED or EXCLUSIVE lock after the transaction was committed:
 #
 #   * The journal-mode is set to something other than 'delete', and
 #   * there exists one or more active read-only statements, and
 #   * a transaction that modified zero database pages is committed.
 #
 set temp_status unlocked
 if {$TEMP_STORE>=2} {set temp_status unknown}
 do_test lock-7.1 {
   set STMT [sqlite3_prepare $DB "SELECT * FROM sqlite_master" -1 TAIL]
   sqlite3_step $STMT
 } {SQLITE_ROW}
 do_test lock-7.2 {
   execsql { PRAGMA lock_status }
 } [list main shared temp $temp_status]
 do_test lock-7.3 {
   execsql {
     PRAGMA journal_mode = truncate;
     BEGIN;
     UPDATE t4 SET a = 10 WHERE 0;
     COMMIT;
   }
   execsql { PRAGMA lock_status }
 } [list main shared temp $temp_status]
 do_test lock-7.4 {
   sqlite3_finalize $STMT
 } {SQLITE_OK}

 do_test lock-999.1 {
   rename db2 {}
 } {}

 finish_test
	# 2001 September 15
	#
	# 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 implements regression tests for SQLite library. The
	# focus of this script is database locks.
	#
	# $Id: lock.test,v 1.40 2009/06/16 17:49:36 drh Exp $


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

	# Create an alternative connection to the database
	#
	do_test lock-1.0 {
	# Give a complex pathname to stress the path simplification logic in
	# the vxworks driver and in test_async.
	file mkdir tempdir/t1/t2
	sqlite3 db2 ./tempdir/../tempdir/t1/.//t2/../../..//test.db
	set dummy {}
	} {}
	do_test lock-1.1 {
	execsql {SELECT name FROM sqlite_master WHERE type='table' ORDER BY name}
	} {}
	do_test lock-1.2 {
	execsql {SELECT name FROM sqlite_master WHERE type='table' ORDER BY name} db2
	} {}
	do_test lock-1.3 {
	execsql {CREATE TABLE t1(a int, b int)}
	execsql {SELECT name FROM sqlite_master WHERE type='table' ORDER BY name}
	} {t1}
	do_test lock-1.5 {
	catchsql {
	SELECT name FROM sqlite_master WHERE type='table' ORDER BY name
	} db2
	} {0 t1}

	do_test lock-1.6 {
	execsql {INSERT INTO t1 VALUES(1,2)}
	execsql {SELECT * FROM t1}
	} {1 2}
	# Update: The schema is now brought up to date by test lock-1.5.
	# do_test lock-1.7.1 {
	# catchsql {SELECT * FROM t1} db2
	# } {1 {no such table: t1}}
	do_test lock-1.7.2 {
	catchsql {SELECT * FROM t1} db2
	} {0 {1 2}}
	do_test lock-1.8 {
	execsql {UPDATE t1 SET a=b, b=a} db2
	execsql {SELECT * FROM t1} db2
	} {2 1}
	do_test lock-1.9 {
	execsql {SELECT * FROM t1}
	} {2 1}
	do_test lock-1.10 {
	execsql {BEGIN TRANSACTION}
	execsql {UPDATE t1 SET a = 0 WHERE 0}
	execsql {SELECT * FROM t1}
	} {2 1}
	do_test lock-1.11 {
	catchsql {SELECT * FROM t1} db2
	} {0 {2 1}}
	do_test lock-1.12 {
	execsql {ROLLBACK}
	catchsql {SELECT * FROM t1}
	} {0 {2 1}}

	do_test lock-1.13 {
	execsql {CREATE TABLE t2(x int, y int)}
	execsql {INSERT INTO t2 VALUES(8,9)}
	execsql {SELECT * FROM t2}
	} {8 9}
	do_test lock-1.14.1 {
	catchsql {SELECT * FROM t2} db2
	} {0 {8 9}}
	do_test lock-1.14.2 {
	catchsql {SELECT * FROM t1} db2
	} {0 {2 1}}
	do_test lock-1.15 {
	catchsql {SELECT * FROM t2} db2
	} {0 {8 9}}

	do_test lock-1.16 {
	db eval {SELECT * FROM t1} qv {
	set x [db eval {SELECT * FROM t1}]
	}
	set x
	} {2 1}
	do_test lock-1.17 {
	db eval {SELECT * FROM t1} qv {
	set x [db eval {SELECT * FROM t2}]
	}
	set x
	} {8 9}

	# You cannot UPDATE a table from within the callback of a SELECT
	# on that same table because the SELECT has the table locked.
	#
	# 2006-08-16: Reads no longer block writes within the same
	# database connection.
	#
	#do_test lock-1.18 {
	# db eval {SELECT * FROM t1} qv {
	# set r [catch {db eval {UPDATE t1 SET a=b, b=a}} msg]
	# lappend r $msg
	# }
	# set r
	#} {1 {database table is locked}}

	# But you can UPDATE a different table from the one that is used in
	# the SELECT.
	#
	do_test lock-1.19 {
	db eval {SELECT * FROM t1} qv {
	set r [catch {db eval {UPDATE t2 SET x=y, y=x}} msg]
	lappend r $msg
	}
	set r
	} {0 {}}
	do_test lock-1.20 {
	execsql {SELECT * FROM t2}
	} {9 8}

	# It is possible to do a SELECT of the same table within the
	# callback of another SELECT on that same table because two
	# or more read-only cursors can be open at once.
	#
	do_test lock-1.21 {
	db eval {SELECT * FROM t1} qv {
	set r [catch {db eval {SELECT a FROM t1}} msg]
	lappend r $msg
	}
	set r
	} {0 2}

	# Under UNIX you can do two SELECTs at once with different database
	# connections, because UNIX supports reader/writer locks. Under windows,
	# this is not possible.
	#
	if {$::tcl_platform(platform)=="unix"} {
	do_test lock-1.22 {
	db eval {SELECT * FROM t1} qv {
	set r [catch {db2 eval {SELECT a FROM t1}} msg]
	lappend r $msg
	}
	set r
	} {0 2}
	}
	integrity_check lock-1.23

	# If one thread has a transaction another thread cannot start
	# a transaction. -> Not true in version 3.0. But if one thread
	# as a RESERVED lock another thread cannot acquire one.
	#
	do_test lock-2.1 {
	execsql {BEGIN TRANSACTION}
	execsql {UPDATE t1 SET a = 0 WHERE 0}
	execsql {BEGIN TRANSACTION} db2
	set r [catch {execsql {UPDATE t1 SET a = 0 WHERE 0} db2} msg]
	execsql {ROLLBACK} db2
	lappend r $msg
	} {1 {database is locked}}

	# A thread can read when another has a RESERVED lock.
	#
	do_test lock-2.2 {
	catchsql {SELECT * FROM t2} db2
	} {0 {9 8}}

	# If the other thread (the one that does not hold the transaction with
	# a RESERVED lock) tries to get a RESERVED lock, we do get a busy callback
	# as long as we were not orginally holding a READ lock.
	#
	do_test lock-2.3.1 {
	proc callback {count} {
	set ::callback_value $count
	break
	}
	set ::callback_value {}
	db2 busy callback
	# db2 does not hold a lock so we should get a busy callback here
	set r [catch {execsql {UPDATE t1 SET a=b, b=a} db2} msg]
	lappend r $msg
	lappend r $::callback_value
	} {1 {database is locked} 0}
	do_test lock-2.3.2 {
	set ::callback_value {}
	execsql {BEGIN; SELECT rowid FROM sqlite_master LIMIT 1} db2
	# This time db2 does hold a read lock. No busy callback this time.
	set r [catch {execsql {UPDATE t1 SET a=b, b=a} db2} msg]
	lappend r $msg
	lappend r $::callback_value
	} {1 {database is locked} {}}
	catch {execsql {ROLLBACK} db2}
	do_test lock-2.4.1 {
	proc callback {count} {
	lappend ::callback_value $count
	if {$count>4} break
	}
	set ::callback_value {}
	db2 busy callback
	# We get a busy callback because db2 is not holding a lock
	set r [catch {execsql {UPDATE t1 SET a=b, b=a} db2} msg]
	lappend r $msg
	lappend r $::callback_value
	} {1 {database is locked} {0 1 2 3 4 5}}
	do_test lock-2.4.2 {
	proc callback {count} {
	lappend ::callback_value $count
	if {$count>4} break
	}
	set ::callback_value {}
	db2 busy callback
	execsql {BEGIN; SELECT rowid FROM sqlite_master LIMIT 1} db2
	# No busy callback this time because we are holding a lock
	set r [catch {execsql {UPDATE t1 SET a=b, b=a} db2} msg]
	lappend r $msg
	lappend r $::callback_value
	} {1 {database is locked} {}}
	catch {execsql {ROLLBACK} db2}
	do_test lock-2.5 {
	proc callback {count} {
	lappend ::callback_value $count
	if {$count>4} break
	}
	set ::callback_value {}
	db2 busy callback
	set r [catch {execsql {SELECT * FROM t1} db2} msg]
	lappend r $msg
	lappend r $::callback_value
	} {0 {2 1} {}}
	execsql {ROLLBACK}

	# Test the built-in busy timeout handler
	#
	do_test lock-2.8 {
	db2 timeout 400
	execsql BEGIN
	execsql {UPDATE t1 SET a = 0 WHERE 0}
	catchsql {BEGIN EXCLUSIVE;} db2
	} {1 {database is locked}}
	do_test lock-2.9 {
	db2 timeout 0
	execsql COMMIT
	} {}
	integrity_check lock-2.10

	# Try to start two transactions in a row
	#
	do_test lock-3.1 {
	execsql {BEGIN TRANSACTION}
	set r [catch {execsql {BEGIN TRANSACTION}} msg]
	execsql {ROLLBACK}
	lappend r $msg
	} {1 {cannot start a transaction within a transaction}}
	integrity_check lock-3.2

	# Make sure the busy handler and error messages work when
	# opening a new pointer to the database while another pointer
	# has the database locked.
	#
	do_test lock-4.1 {
	db2 close
	catch {db eval ROLLBACK}
	db eval BEGIN
	db eval {UPDATE t1 SET a=0 WHERE 0}
	sqlite3 db2 ./test.db
	catchsql {UPDATE t1 SET a=0} db2
	} {1 {database is locked}}
	do_test lock-4.2 {
	set ::callback_value {}
	set rc [catch {db2 eval {UPDATE t1 SET a=0}} msg]
	lappend rc $msg $::callback_value
	} {1 {database is locked} {}}
	do_test lock-4.3 {
	proc callback {count} {
	lappend ::callback_value $count
	if {$count>4} break
	}
	db2 busy callback
	set rc [catch {db2 eval {UPDATE t1 SET a=0}} msg]
	lappend rc $msg $::callback_value
	} {1 {database is locked} {0 1 2 3 4 5}}
	execsql {ROLLBACK}

	# When one thread is writing, other threads cannot read. Except if the
	# writing thread is writing to its temporary tables, the other threads
	# can still read. -> Not so in 3.0. One thread can read while another
	# holds a RESERVED lock.
	#
	proc tx_exec {sql} {
	db2 eval $sql
	}
	do_test lock-5.1 {
	execsql {
	SELECT * FROM t1
	}
	} {2 1}
	do_test lock-5.2 {
	db function tx_exec tx_exec
	catchsql {
	INSERT INTO t1(a,b) SELECT 3, tx_exec('SELECT y FROM t2 LIMIT 1');
	}
	} {0 {}}

	ifcapable tempdb {
	do_test lock-5.3 {
	execsql {
	CREATE TEMP TABLE t3(x);
	SELECT * FROM t3;
	}
	} {}
	do_test lock-5.4 {
	catchsql {
	INSERT INTO t3 SELECT tx_exec('SELECT y FROM t2 LIMIT 1');
	}
	} {0 {}}
	do_test lock-5.5 {
	execsql {
	SELECT * FROM t3;
	}
	} {8}
	do_test lock-5.6 {
	catchsql {
	UPDATE t1 SET a=tx_exec('SELECT x FROM t2');
	}
	} {0 {}}
	do_test lock-5.7 {
	execsql {
	SELECT * FROM t1;
	}
	} {9 1 9 8}
	do_test lock-5.8 {
	catchsql {
	UPDATE t3 SET x=tx_exec('SELECT x FROM t2');
	}
	} {0 {}}
	do_test lock-5.9 {
	execsql {
	SELECT * FROM t3;
	}
	} {9}
	}

	do_test lock-6.1 {
	execsql {
	CREATE TABLE t4(a PRIMARY KEY, b);
	INSERT INTO t4 VALUES(1, 'one');
	INSERT INTO t4 VALUES(2, 'two');
	INSERT INTO t4 VALUES(3, 'three');
	}

	set STMT [sqlite3_prepare $DB "SELECT * FROM sqlite_master" -1 TAIL]
	sqlite3_step $STMT

	execsql { DELETE FROM t4 }
	execsql { SELECT * FROM sqlite_master } db2
	execsql { SELECT * FROM t4 } db2
	} {}

	do_test lock-6.2 {
	execsql {
	BEGIN;
	INSERT INTO t4 VALUES(1, 'one');
	INSERT INTO t4 VALUES(2, 'two');
	INSERT INTO t4 VALUES(3, 'three');
	COMMIT;
	}

	execsql { SELECT * FROM t4 } db2
	} {1 one 2 two 3 three}

	do_test lock-6.3 {
	execsql { SELECT a FROM t4 ORDER BY a } db2
	} {1 2 3}

	do_test lock-6.4 {
	execsql { PRAGMA integrity_check } db2
	} {ok}

	do_test lock-6.5 {
	sqlite3_finalize $STMT
	} {SQLITE_OK}

	# At one point the following set of conditions would cause SQLite to
	# retain a RESERVED or EXCLUSIVE lock after the transaction was committed:
	#
	# * The journal-mode is set to something other than 'delete', and
	# * there exists one or more active read-only statements, and
	# * a transaction that modified zero database pages is committed.
	#
	set temp_status unlocked
	if {$TEMP_STORE>=2} {set temp_status unknown}
	do_test lock-7.1 {
	set STMT [sqlite3_prepare $DB "SELECT * FROM sqlite_master" -1 TAIL]
	sqlite3_step $STMT
	} {SQLITE_ROW}
	do_test lock-7.2 {
	execsql { PRAGMA lock_status }
	} [list main shared temp $temp_status]
	do_test lock-7.3 {
	execsql {
	PRAGMA journal_mode = truncate;
	BEGIN;
	UPDATE t4 SET a = 10 WHERE 0;
	COMMIT;
	}
	execsql { PRAGMA lock_status }
	} [list main shared temp $temp_status]
	do_test lock-7.4 {
	sqlite3_finalize $STMT
	} {SQLITE_OK}

	do_test lock-999.1 {
	rename db2 {}
	} {}

	finish_test