third_party/sqlite/src/test/thread1.test - cobalt - Git at Google

 # 2003 December 18
 #
 # 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 multithreading behavior
 #
 # $Id: thread1.test,v 1.8 2008/10/07 15:25:49 drh Exp $


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

 # Skip this whole file if the thread testing code is not enabled
 #
 if {[run_thread_tests]==0} { finish_test ; return }
 if {[llength [info command thread_step]]==0 || [sqlite3 -has-codec]} {
   finish_test
   return
 }

 # Create some data to work with
 #
 do_test thread1-1.1 {
   execsql {
     CREATE TABLE t1(a,b);
     INSERT INTO t1 VALUES(1,'abcdefgh');
     INSERT INTO t1 SELECT a+1, b||b FROM t1;
     INSERT INTO t1 SELECT a+2, b||b FROM t1;
     INSERT INTO t1 SELECT a+4, b||b FROM t1;
     SELECT count(*), max(length(b)) FROM t1;
   }
 } {8 64}

 # Interleave two threads on read access.  Then make sure a third
 # thread can write the database.  In other words:
 #
 #    read-lock A
 #    read-lock B
 #    unlock A
 #    unlock B
 #    write-lock C
 #
 # At one point, the write-lock of C would fail on Linux.
 #
 do_test thread1-1.2 {
   thread_create A test.db
   thread_create B test.db
   thread_create C test.db
   thread_compile A {SELECT a FROM t1}
   thread_step A
   thread_result A
 } SQLITE_ROW
 do_test thread1-1.3 {
   thread_argc A
 } 1
 do_test thread1-1.4 {
   thread_argv A 0
 } 1
 do_test thread1-1.5 {
   thread_compile B {SELECT b FROM t1}
   thread_step B
   thread_result B
 } SQLITE_ROW
 do_test thread1-1.6 {
   thread_argc B
 } 1
 do_test thread1-1.7 {
   thread_argv B 0
 } abcdefgh
 do_test thread1-1.8 {
   thread_finalize A
   thread_result A
 } SQLITE_OK
 do_test thread1-1.9 {
   thread_finalize B
   thread_result B
 } SQLITE_OK
 do_test thread1-1.10 {
   thread_compile C {CREATE TABLE t2(x,y)}
   thread_step C
   thread_result C
 } SQLITE_DONE
 do_test thread1-1.11 {
   thread_finalize C
   thread_result C
 } SQLITE_OK
 do_test thread1-1.12 {
   catchsql {SELECT name FROM sqlite_master}
   execsql {SELECT name FROM sqlite_master}
 } {t1 t2}


 #
 # The following tests - thread1-2.* - test the following scenario:
 #
 # 1:  Read-lock thread A
 # 2:  Read-lock thread B
 # 3:  Attempt to write in thread C -> SQLITE_BUSY
 # 4:  Check db write failed from main thread.
 # 5:  Unlock from thread A.
 # 6:  Attempt to write in thread C -> SQLITE_BUSY
 # 7:  Check db write failed from main thread.
 # 8:  Unlock from thread B.
 # 9:  Attempt to write in thread C -> SQLITE_DONE
 # 10: Finalize the write from thread C
 # 11: Check db write succeeded from main thread.
 #
 do_test thread1-2.1 {
   thread_halt *
   thread_create A test.db
   thread_compile A {SELECT a FROM t1}
   thread_step A
   thread_result A
 } SQLITE_ROW
 do_test thread1-2.2 {
   thread_create B test.db
   thread_compile B {SELECT b FROM t1}
   thread_step B
   thread_result B
 } SQLITE_ROW
 do_test thread1-2.3 {
   thread_create C test.db
   thread_compile C {INSERT INTO t2 VALUES(98,99)}
   thread_step C
   thread_result C
   thread_finalize C
   thread_result C
 } SQLITE_BUSY

 do_test thread1-2.4 {
   execsql {SELECT * FROM t2}
 } {}

 do_test thread1-2.5 {
   thread_finalize A
   thread_result A
 } SQLITE_OK
 do_test thread1-2.6 {
   thread_compile C {INSERT INTO t2 VALUES(98,99)}
   thread_step C
   thread_result C
   thread_finalize C
   thread_result C
 } SQLITE_BUSY
 do_test thread1-2.7 {
   execsql {SELECT * FROM t2}
 } {}
 do_test thread1-2.8 {
   thread_finalize B
   thread_result B
 } SQLITE_OK
 do_test thread1-2.9 {
   thread_compile C {INSERT INTO t2 VALUES(98,99)}
   thread_step C
   thread_result C
 } SQLITE_DONE
 do_test thread1-2.10 {
   thread_finalize C
   thread_result C
 } SQLITE_OK
 do_test thread1-2.11 {
   execsql {SELECT * FROM t2}
 } {98 99}

 thread_halt *
 finish_test
	# 2003 December 18
	#
	# 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 multithreading behavior
	#
	# $Id: thread1.test,v 1.8 2008/10/07 15:25:49 drh Exp $


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

	# Skip this whole file if the thread testing code is not enabled
	#
	if {[run_thread_tests]==0} { finish_test ; return }
	if {[llength [info command thread_step]]==0 \|\| [sqlite3 -has-codec]} {
	finish_test
	return
	}

	# Create some data to work with
	#
	do_test thread1-1.1 {
	execsql {
	CREATE TABLE t1(a,b);
	INSERT INTO t1 VALUES(1,'abcdefgh');
	INSERT INTO t1 SELECT a+1, b\|\|b FROM t1;
	INSERT INTO t1 SELECT a+2, b\|\|b FROM t1;
	INSERT INTO t1 SELECT a+4, b\|\|b FROM t1;
	SELECT count(*), max(length(b)) FROM t1;
	}
	} {8 64}

	# Interleave two threads on read access. Then make sure a third
	# thread can write the database. In other words:
	#
	# read-lock A
	# read-lock B
	# unlock A
	# unlock B
	# write-lock C
	#
	# At one point, the write-lock of C would fail on Linux.
	#
	do_test thread1-1.2 {
	thread_create A test.db
	thread_create B test.db
	thread_create C test.db
	thread_compile A {SELECT a FROM t1}
	thread_step A
	thread_result A
	} SQLITE_ROW
	do_test thread1-1.3 {
	thread_argc A
	} 1
	do_test thread1-1.4 {
	thread_argv A 0
	} 1
	do_test thread1-1.5 {
	thread_compile B {SELECT b FROM t1}
	thread_step B
	thread_result B
	} SQLITE_ROW
	do_test thread1-1.6 {
	thread_argc B
	} 1
	do_test thread1-1.7 {
	thread_argv B 0
	} abcdefgh
	do_test thread1-1.8 {
	thread_finalize A
	thread_result A
	} SQLITE_OK
	do_test thread1-1.9 {
	thread_finalize B
	thread_result B
	} SQLITE_OK
	do_test thread1-1.10 {
	thread_compile C {CREATE TABLE t2(x,y)}
	thread_step C
	thread_result C
	} SQLITE_DONE
	do_test thread1-1.11 {
	thread_finalize C
	thread_result C
	} SQLITE_OK
	do_test thread1-1.12 {
	catchsql {SELECT name FROM sqlite_master}
	execsql {SELECT name FROM sqlite_master}
	} {t1 t2}


	#
	# The following tests - thread1-2.* - test the following scenario:
	#
	# 1: Read-lock thread A
	# 2: Read-lock thread B
	# 3: Attempt to write in thread C -> SQLITE_BUSY
	# 4: Check db write failed from main thread.
	# 5: Unlock from thread A.
	# 6: Attempt to write in thread C -> SQLITE_BUSY
	# 7: Check db write failed from main thread.
	# 8: Unlock from thread B.
	# 9: Attempt to write in thread C -> SQLITE_DONE
	# 10: Finalize the write from thread C
	# 11: Check db write succeeded from main thread.
	#
	do_test thread1-2.1 {
	thread_halt *
	thread_create A test.db
	thread_compile A {SELECT a FROM t1}
	thread_step A
	thread_result A
	} SQLITE_ROW
	do_test thread1-2.2 {
	thread_create B test.db
	thread_compile B {SELECT b FROM t1}
	thread_step B
	thread_result B
	} SQLITE_ROW
	do_test thread1-2.3 {
	thread_create C test.db
	thread_compile C {INSERT INTO t2 VALUES(98,99)}
	thread_step C
	thread_result C
	thread_finalize C
	thread_result C
	} SQLITE_BUSY

	do_test thread1-2.4 {
	execsql {SELECT * FROM t2}
	} {}

	do_test thread1-2.5 {
	thread_finalize A
	thread_result A
	} SQLITE_OK
	do_test thread1-2.6 {
	thread_compile C {INSERT INTO t2 VALUES(98,99)}
	thread_step C
	thread_result C
	thread_finalize C
	thread_result C
	} SQLITE_BUSY
	do_test thread1-2.7 {
	execsql {SELECT * FROM t2}
	} {}
	do_test thread1-2.8 {
	thread_finalize B
	thread_result B
	} SQLITE_OK
	do_test thread1-2.9 {
	thread_compile C {INSERT INTO t2 VALUES(98,99)}
	thread_step C
	thread_result C
	} SQLITE_DONE
	do_test thread1-2.10 {
	thread_finalize C
	thread_result C
	} SQLITE_OK
	do_test thread1-2.11 {
	execsql {SELECT * FROM t2}
	} {98 99}

	thread_halt *
	finish_test