src/test/imposter1.test - chromium/src/third_party/sqlite - Git at Google

 # 2015-01-30
 #
 # 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 implements tests for SQLite library.
 #
 # The focus of this file is adding extra entries in the symbol table
 # using sqlite3_test_control(SQLITE_TESTCTRL_IMPOSTER) and verifying that
 # SQLite handles those as expected.
 #

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

 # Create a bunch of data to sort against
 #
 do_test imposter-1.0 {
   execsql {
     CREATE TABLE t1(a INTEGER PRIMARY KEY, b, c, d NOT NULL);
     CREATE INDEX t1b ON t1(b);
     CREATE UNIQUE INDEX t1c ON t1(c);
     WITH RECURSIVE c(i) AS (VALUES(1) UNION ALL SELECT i+1 FROM c WHERE i<30)
       INSERT INTO t1(a,b,c,d) SELECT i,1000+i,2000+i,3000+i FROM c;
   }
   set t1_root [db one {SELECT rootpage FROM sqlite_master WHERE name='t1'}]
   set t1b_root [db one {SELECT rootpage FROM sqlite_master WHERE name='t1b'}]
   set t1c_root [db one {SELECT rootpage FROM sqlite_master WHERE name='t1c'}]

   # Create an imposter table that uses the same b-tree as t1 but which does
   # not have the indexes
   #
   sqlite3_test_control SQLITE_TESTCTRL_IMPOSTER db main 1 $t1_root
   db eval {CREATE TABLE xt1(a,b,c,d)}

   # And create an imposter table for the t1c index.
   sqlite3_test_control SQLITE_TESTCTRL_IMPOSTER db main 1 $t1c_root
   db eval {CREATE TABLE xt1c(c,rowid,PRIMARY KEY(c,rowid))WITHOUT ROWID;}

   # Go out of imposter mode for now.
   sqlite3_test_control SQLITE_TESTCTRL_IMPOSTER db main 0 0

   # Create triggers to record changes to xt1.
   #
   db eval {
     CREATE TEMP TABLE chnglog(desc TEXT);
     CREATE TEMP TRIGGER xt1_del AFTER DELETE ON xt1 BEGIN
       INSERT INTO chnglog VALUES(
            printf('DELETE t1: rowid=%d, a=%s, b=%s, c=%s, d=%s',
                   old.rowid, quote(old.a), quote(old.b), quote(old.c),
                   quote(old.d)));
     END;
     CREATE TEMP TRIGGER xt1_ins AFTER INSERT ON xt1 BEGIN
       INSERT INTO chnglog VALUES(
            printf('INSERT t1:  rowid=%d, a=%s, b=%s, c=%s, d=%s',
                   new.rowid, quote(new.a), quote(new.b), quote(new.c),
                   quote(new.d)));
     END;
   }
 } {}

 # The xt1 table has separate xt1.rowid and xt1.a columns.  The xt1.rowid
 # column corresponds to t1.rowid and t1.a, but the xt1.a column is always
 # NULL
 #
 do_execsql_test imposter-1.1 {
   SELECT rowid FROM xt1 WHERE a IS NOT NULL;
 } {}
 do_execsql_test imposter-1.2 {
   SELECT a,b,c,d FROM t1 EXCEPT SELECT rowid,b,c,d FROM xt1;
   SELECT rowid,b,c,d FROM xt1 EXCEPT SELECT a,b,c,d FROM t1;
 } {}


 # Make changes via the xt1 shadow table.  This will not update the
 # indexes on t1 nor check the uniqueness constraint on t1.c nor check
 # the NOT NULL constraint on t1.d, resulting in a logically inconsistent
 # database.
 #
 do_execsql_test imposter-1.3 {
   DELETE FROM xt1 WHERE rowid=5;
   INSERT INTO xt1(rowid,a,b,c,d) VALUES(99,'hello',1099,2022,NULL);
   SELECT * FROM chnglog ORDER BY rowid;
 } [list \
   {DELETE t1: rowid=5, a=NULL, b=1005, c=2005, d=3005} \
   {INSERT t1:  rowid=99, a='hello', b=1099, c=2022, d=NULL} \
 ]

 do_execsql_test imposter-1.4a {
   PRAGMA integrity_check;
 } {/NULL value in t1.d/}
 do_execsql_test imposter-1.4b {
   PRAGMA integrity_check;
 } {/row # missing from index t1b/}
 do_execsql_test imposter-1.4c {
   PRAGMA integrity_check;
 } {/row # missing from index t1c/}

 # Cleanup the corruption.
 # Then demonstrate that the xt1c imposter table can insert non-unique
 # and NULL values into the UNIQUE index.
 #
 do_execsql_test imposter-2.0 {
   DELETE FROM t1;
   WITH RECURSIVE c(i) AS (VALUES(1) UNION ALL SELECT i+1 FROM c WHERE i<10)
    INSERT INTO t1(a,b,c,d) SELECT i,i,i,i FROM c;
   UPDATE xt1c SET c=NULL WHERE rowid=5;
   PRAGMA integrity_check;
 } {/row # missing from index t1c/}

 do_execsql_test imposter-2.1 {
   DELETE FROM t1;
   WITH RECURSIVE c(i) AS (VALUES(1) UNION ALL SELECT i+1 FROM c WHERE i<10)
    INSERT INTO t1(a,b,c,d) SELECT i,i,i,i FROM c;
   UPDATE xt1c SET c=99 WHERE rowid IN (5,7,9);
   SELECT c FROM t1 ORDER BY c;
 } {1 2 3 4 6 8 10 99 99 99}
 do_execsql_test imposter-2.2 {
   UPDATE xt1 SET c=99 WHERE rowid IN (5,7,9);
   PRAGMA integrity_check;
 } {/non-unique entry in index t1c/}

 # Erase the imposter tables
 #
 do_test imposter-3.1 {
   sqlite3_test_control SQLITE_TESTCTRL_IMPOSTER db main 0 1
   db eval {
     DELETE FROM t1 WHERE rowid IN (5,7,9);
     PRAGMA integrity_check;
   }
 } {ok}


 finish_test
	# 2015-01-30
	#
	# 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 implements tests for SQLite library.
	#
	# The focus of this file is adding extra entries in the symbol table
	# using sqlite3_test_control(SQLITE_TESTCTRL_IMPOSTER) and verifying that
	# SQLite handles those as expected.
	#

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

	# Create a bunch of data to sort against
	#
	do_test imposter-1.0 {
	execsql {
	CREATE TABLE t1(a INTEGER PRIMARY KEY, b, c, d NOT NULL);
	CREATE INDEX t1b ON t1(b);
	CREATE UNIQUE INDEX t1c ON t1(c);
	WITH RECURSIVE c(i) AS (VALUES(1) UNION ALL SELECT i+1 FROM c WHERE i<30)
	INSERT INTO t1(a,b,c,d) SELECT i,1000+i,2000+i,3000+i FROM c;
	}
	set t1_root [db one {SELECT rootpage FROM sqlite_master WHERE name='t1'}]
	set t1b_root [db one {SELECT rootpage FROM sqlite_master WHERE name='t1b'}]
	set t1c_root [db one {SELECT rootpage FROM sqlite_master WHERE name='t1c'}]

	# Create an imposter table that uses the same b-tree as t1 but which does
	# not have the indexes
	#
	sqlite3_test_control SQLITE_TESTCTRL_IMPOSTER db main 1 $t1_root
	db eval {CREATE TABLE xt1(a,b,c,d)}

	# And create an imposter table for the t1c index.
	sqlite3_test_control SQLITE_TESTCTRL_IMPOSTER db main 1 $t1c_root
	db eval {CREATE TABLE xt1c(c,rowid,PRIMARY KEY(c,rowid))WITHOUT ROWID;}

	# Go out of imposter mode for now.
	sqlite3_test_control SQLITE_TESTCTRL_IMPOSTER db main 0 0

	# Create triggers to record changes to xt1.
	#
	db eval {
	CREATE TEMP TABLE chnglog(desc TEXT);
	CREATE TEMP TRIGGER xt1_del AFTER DELETE ON xt1 BEGIN
	INSERT INTO chnglog VALUES(
	printf('DELETE t1: rowid=%d, a=%s, b=%s, c=%s, d=%s',
	old.rowid, quote(old.a), quote(old.b), quote(old.c),
	quote(old.d)));
	END;
	CREATE TEMP TRIGGER xt1_ins AFTER INSERT ON xt1 BEGIN
	INSERT INTO chnglog VALUES(
	printf('INSERT t1: rowid=%d, a=%s, b=%s, c=%s, d=%s',
	new.rowid, quote(new.a), quote(new.b), quote(new.c),
	quote(new.d)));
	END;
	}
	} {}

	# The xt1 table has separate xt1.rowid and xt1.a columns. The xt1.rowid
	# column corresponds to t1.rowid and t1.a, but the xt1.a column is always
	# NULL
	#
	do_execsql_test imposter-1.1 {
	SELECT rowid FROM xt1 WHERE a IS NOT NULL;
	} {}
	do_execsql_test imposter-1.2 {
	SELECT a,b,c,d FROM t1 EXCEPT SELECT rowid,b,c,d FROM xt1;
	SELECT rowid,b,c,d FROM xt1 EXCEPT SELECT a,b,c,d FROM t1;
	} {}


	# Make changes via the xt1 shadow table. This will not update the
	# indexes on t1 nor check the uniqueness constraint on t1.c nor check
	# the NOT NULL constraint on t1.d, resulting in a logically inconsistent
	# database.
	#
	do_execsql_test imposter-1.3 {
	DELETE FROM xt1 WHERE rowid=5;
	INSERT INTO xt1(rowid,a,b,c,d) VALUES(99,'hello',1099,2022,NULL);
	SELECT * FROM chnglog ORDER BY rowid;
	} [list \
	{DELETE t1: rowid=5, a=NULL, b=1005, c=2005, d=3005} \
	{INSERT t1: rowid=99, a='hello', b=1099, c=2022, d=NULL} \
	]

	do_execsql_test imposter-1.4a {
	PRAGMA integrity_check;
	} {/NULL value in t1.d/}
	do_execsql_test imposter-1.4b {
	PRAGMA integrity_check;
	} {/row # missing from index t1b/}
	do_execsql_test imposter-1.4c {
	PRAGMA integrity_check;
	} {/row # missing from index t1c/}

	# Cleanup the corruption.
	# Then demonstrate that the xt1c imposter table can insert non-unique
	# and NULL values into the UNIQUE index.
	#
	do_execsql_test imposter-2.0 {
	DELETE FROM t1;
	WITH RECURSIVE c(i) AS (VALUES(1) UNION ALL SELECT i+1 FROM c WHERE i<10)
	INSERT INTO t1(a,b,c,d) SELECT i,i,i,i FROM c;
	UPDATE xt1c SET c=NULL WHERE rowid=5;
	PRAGMA integrity_check;
	} {/row # missing from index t1c/}

	do_execsql_test imposter-2.1 {
	DELETE FROM t1;
	WITH RECURSIVE c(i) AS (VALUES(1) UNION ALL SELECT i+1 FROM c WHERE i<10)
	INSERT INTO t1(a,b,c,d) SELECT i,i,i,i FROM c;
	UPDATE xt1c SET c=99 WHERE rowid IN (5,7,9);
	SELECT c FROM t1 ORDER BY c;
	} {1 2 3 4 6 8 10 99 99 99}
	do_execsql_test imposter-2.2 {
	UPDATE xt1 SET c=99 WHERE rowid IN (5,7,9);
	PRAGMA integrity_check;
	} {/non-unique entry in index t1c/}

	# Erase the imposter tables
	#
	do_test imposter-3.1 {
	sqlite3_test_control SQLITE_TESTCTRL_IMPOSTER db main 0 1
	db eval {
	DELETE FROM t1 WHERE rowid IN (5,7,9);
	PRAGMA integrity_check;
	}
	} {ok}


	finish_test