test/types.test - external/github.com/sqlite/sqlite - 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. Specfically
 # it tests that the different storage classes (integer, real, text etc.)
 # all work correctly.
 #
 # $Id: types.test,v 1.20 2009/06/29 06:00:37 danielk1977 Exp $

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

 # Tests in this file are organized roughly as follows:
 #
 # types-1.*.*: Test that values are stored using the expected storage
 #              classes when various forms of literals are inserted into
 #              columns with different affinities.
 # types-1.1.*: INSERT INTO <table> VALUES(...)
 # types-1.2.*: INSERT INTO <table> SELECT...
 # types-1.3.*: UPDATE <table> SET...
 #
 # types-2.*.*: Check that values can be stored and retrieving using the
 #              various storage classes.
 # types-2.1.*: INTEGER
 # types-2.2.*: REAL
 # types-2.3.*: NULL
 # types-2.4.*: TEXT
 # types-2.5.*: Records with a few different storage classes.
 #
 # types-3.*: Test that the '=' operator respects manifest types.
 #

 # Disable encryption on the database for this test.
 db close
 set DB [sqlite3 db test.db; sqlite3_connection_pointer db]
 sqlite3_rekey $DB {}

 # Create a table with one column for each type of affinity
 do_test types-1.1.0 {
   execsql {
     CREATE TABLE t1(i integer, n numeric, t text, o blob);
   }
 } {}

 # Each element of the following list represents one test case.
 #
 # The first value of each sub-list is an SQL literal. The following
 # four value are the storage classes that would be used if the
 # literal were inserted into a column with affinity INTEGER, NUMERIC, TEXT
 # or NONE, respectively.
 set values {
   { 5.0    integer integer text real    }
   { 5.1    real    real    text real    }
   { 5      integer integer text integer }
   { '5.0'  integer integer text text    }
   { '5.1'  real    real    text text    }
   { '-5.0' integer integer text text    }
   { '-5.0' integer integer text text    }
   { '5'    integer integer text text    }
   { 'abc'  text    text    text text    }
   { NULL   null    null    null null    }
 }
 ifcapable {bloblit} {
   lappend values  { X'00'  blob    blob    blob blob    }
 }

 # This code tests that the storage classes specified above (in the $values
 # table) are correctly assigned when values are inserted using a statement
 # of the form:
 #
 # INSERT INTO <table> VALUE(<values>);
 #
 set tnum 1
 foreach val $values {
   set lit [lindex $val 0]
   execsql "DELETE FROM t1;"
   execsql "INSERT INTO t1 VALUES($lit, $lit, $lit, $lit);"
   do_test types-1.1.$tnum {
     execsql {
       SELECT typeof(i), typeof(n), typeof(t), typeof(o) FROM t1;
     }
   } [lrange $val 1 end]
   incr tnum
 }

 # This code tests that the storage classes specified above (in the $values
 # table) are correctly assigned when values are inserted using a statement
 # of the form:
 #
 # INSERT INTO t1 SELECT ....
 #
 set tnum 1
 foreach val $values {
   set lit [lindex $val 0]
   execsql "DELETE FROM t1;"
   execsql "INSERT INTO t1 SELECT $lit, $lit, $lit, $lit;"
   do_test types-1.2.$tnum {
     execsql {
       SELECT typeof(i), typeof(n), typeof(t), typeof(o) FROM t1;
     }
   } [lrange $val 1 end]
   incr tnum
 }

 # This code tests that the storage classes specified above (in the $values
 # table) are correctly assigned when values are inserted using a statement
 # of the form:
 #
 # UPDATE <table> SET <column> = <value>;
 #
 set tnum 1
 foreach val $values {
   set lit [lindex $val 0]
   execsql "UPDATE t1 SET i = $lit, n = $lit, t = $lit, o = $lit;"
   do_test types-1.3.$tnum {
     execsql {
       SELECT typeof(i), typeof(n), typeof(t), typeof(o) FROM t1;
     }
   } [lrange $val 1 end]
   incr tnum
 }

 execsql {
   DROP TABLE t1;
 }

 # Open the table with root-page $rootpage at the btree
 # level. Return a list that is the length of each record
 # in the table, in the tables default scanning order.
 proc record_sizes {rootpage} {
   set bt [btree_open test.db 10]
   btree_begin_transaction $bt
   set c [btree_cursor $bt $rootpage 0]
   btree_first $c
   while 1 {
     lappend res [btree_payload_size $c]
     if {[btree_next $c]} break
   }
   btree_close_cursor $c
   btree_close $bt
   set res
 }


 # Create a table and insert some 1-byte integers. Make sure they
 # can be read back OK. These should be 3 byte records.
 do_test types-2.1.1 {
   execsql {
     CREATE TABLE t1(a integer);
     INSERT INTO t1 VALUES(0);
     INSERT INTO t1 VALUES(120);
     INSERT INTO t1 VALUES(-120);
   }
 } {}
 do_test types-2.1.2 {
   execsql {
     SELECT a FROM t1;
   }
 } {0 120 -120}

 # Try some 2-byte integers (4 byte records)
 do_test types-2.1.3 {
   execsql {
     INSERT INTO t1 VALUES(30000);
     INSERT INTO t1 VALUES(-30000);
   }
 } {}
 do_test types-2.1.4 {
   execsql {
     SELECT a FROM t1;
   }
 } {0 120 -120 30000 -30000}

 # 4-byte integers (6 byte records)
 do_test types-2.1.5 {
   execsql {
     INSERT INTO t1 VALUES(2100000000);
     INSERT INTO t1 VALUES(-2100000000);
   }
 } {}
 do_test types-2.1.6 {
   execsql {
     SELECT a FROM t1;
   }
 } {0 120 -120 30000 -30000 2100000000 -2100000000}

 # 8-byte integers (10 byte records)
 do_test types-2.1.7 {
   execsql {
     INSERT INTO t1 VALUES(9000000*1000000*1000000);
     INSERT INTO t1 VALUES(-9000000*1000000*1000000);
   }
 } {}
 do_test types-2.1.8 {
   execsql {
     SELECT a FROM t1;
   }
 } [list 0 120 -120 30000 -30000 2100000000 -2100000000 \
         9000000000000000000 -9000000000000000000]

 # Check that all the record sizes are as we expected.
 ifcapable legacyformat {
   do_test types-2.1.9 {
     set root [db eval {select rootpage from sqlite_master where name = 't1'}]
     record_sizes $root
   } {3 3 3 4 4 6 6 10 10}
 } else {
   do_test types-2.1.9 {
     set root [db eval {select rootpage from sqlite_master where name = 't1'}]
     record_sizes $root
   } {2 3 3 4 4 6 6 10 10}
 }

 # Insert some reals. These should be 10 byte records.
 do_test types-2.2.1 {
   execsql {
     CREATE TABLE t2(a float);
     INSERT INTO t2 VALUES(0.0);
     INSERT INTO t2 VALUES(12345.678);
     INSERT INTO t2 VALUES(-12345.678);
   }
 } {}
 do_test types-2.2.2 {
   execsql {
     SELECT a FROM t2;
   }
 } {0.0 12345.678 -12345.678}

 # Check that all the record sizes are as we expected.
 ifcapable legacyformat {
   do_test types-2.2.3 {
     set root [db eval {select rootpage from sqlite_master where name = 't2'}]
     record_sizes $root
   } {3 10 10}
 } else {
   do_test types-2.2.3 {
     set root [db eval {select rootpage from sqlite_master where name = 't2'}]
     record_sizes $root
   } {2 10 10}
 }

 # Insert a NULL. This should be a two byte record.
 do_test types-2.3.1 {
   execsql {
     CREATE TABLE t3(a nullvalue);
     INSERT INTO t3 VALUES(NULL);
   }
 } {}
 do_test types-2.3.2 {
   execsql {
     SELECT a ISNULL FROM t3;
   }
 } {1}

 # Check that all the record sizes are as we expected.
 do_test types-2.3.3 {
   set root [db eval {select rootpage from sqlite_master where name = 't3'}]
   record_sizes $root
 } {2}

 # Insert a couple of strings.
 do_test types-2.4.1 {
   set string10 abcdefghij
   set string500 [string repeat $string10 50]
   set string500000 [string repeat $string10 50000]

   execsql "
     CREATE TABLE t4(a string);
     INSERT INTO t4 VALUES('$string10');
     INSERT INTO t4 VALUES('$string500');
     INSERT INTO t4 VALUES('$string500000');
   "
 } {}
 do_test types-2.4.2 {
   execsql {
     SELECT a FROM t4;
   }
 } [list $string10 $string500 $string500000]

 # Check that all the record sizes are as we expected. This is dependant on
 # the database encoding.
 if { $sqlite_options(utf16)==0 || [execsql {pragma encoding}] == "UTF-8" } {
   do_test types-2.4.3 {
     set root [db eval {select rootpage from sqlite_master where name = 't4'}]
     record_sizes $root
   } {12 503 500004}
 } else {
   do_test types-2.4.3 {
     set root [db eval {select rootpage from sqlite_master where name = 't4'}]
     record_sizes $root
   } {22 1003 1000004}
 }

 do_test types-2.5.1 {
   execsql {
     DROP TABLE t1;
     DROP TABLE t2;
     DROP TABLE t3;
     DROP TABLE t4;
     CREATE TABLE t1(a, b, c);
   }
 } {}
 do_test types-2.5.2 {
   set string10 abcdefghij
   set string500 [string repeat $string10 50]
   set string500000 [string repeat $string10 50000]

   execsql "INSERT INTO t1 VALUES(NULL, '$string10', 4000);"
   execsql "INSERT INTO t1 VALUES('$string500', 4000, NULL);"
   execsql "INSERT INTO t1 VALUES(4000, NULL, '$string500000');"
 } {}
 do_test types-2.5.3 {
   execsql {
     SELECT * FROM t1;
   }
 } [list {} $string10 4000 $string500 4000 {} 4000 {} $string500000]

 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. Specfically
	# it tests that the different storage classes (integer, real, text etc.)
	# all work correctly.
	#
	# $Id: types.test,v 1.20 2009/06/29 06:00:37 danielk1977 Exp $

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

	# Tests in this file are organized roughly as follows:
	#
	# types-1..: Test that values are stored using the expected storage
	# classes when various forms of literals are inserted into
	# columns with different affinities.
	# types-1.1.*: INSERT INTO <table> VALUES(...)
	# types-1.2.*: INSERT INTO <table> SELECT...
	# types-1.3.*: UPDATE <table> SET...
	#
	# types-2..: Check that values can be stored and retrieving using the
	# various storage classes.
	# types-2.1.*: INTEGER
	# types-2.2.*: REAL
	# types-2.3.*: NULL
	# types-2.4.*: TEXT
	# types-2.5.*: Records with a few different storage classes.
	#
	# types-3.*: Test that the '=' operator respects manifest types.
	#

	# Disable encryption on the database for this test.
	db close
	set DB [sqlite3 db test.db; sqlite3_connection_pointer db]
	sqlite3_rekey $DB {}

	# Create a table with one column for each type of affinity
	do_test types-1.1.0 {
	execsql {
	CREATE TABLE t1(i integer, n numeric, t text, o blob);
	}
	} {}

	# Each element of the following list represents one test case.
	#
	# The first value of each sub-list is an SQL literal. The following
	# four value are the storage classes that would be used if the
	# literal were inserted into a column with affinity INTEGER, NUMERIC, TEXT
	# or NONE, respectively.
	set values {
	{ 5.0 integer integer text real }
	{ 5.1 real real text real }
	{ 5 integer integer text integer }
	{ '5.0' integer integer text text }
	{ '5.1' real real text text }
	{ '-5.0' integer integer text text }
	{ '-5.0' integer integer text text }
	{ '5' integer integer text text }
	{ 'abc' text text text text }
	{ NULL null null null null }
	}
	ifcapable {bloblit} {
	lappend values { X'00' blob blob blob blob }
	}

	# This code tests that the storage classes specified above (in the $values
	# table) are correctly assigned when values are inserted using a statement
	# of the form:
	#
	# INSERT INTO <table> VALUE(<values>);
	#
	set tnum 1
	foreach val $values {
	set lit [lindex $val 0]
	execsql "DELETE FROM t1;"
	execsql "INSERT INTO t1 VALUES($lit, $lit, $lit, $lit);"
	do_test types-1.1.$tnum {
	execsql {
	SELECT typeof(i), typeof(n), typeof(t), typeof(o) FROM t1;
	}
	} [lrange $val 1 end]
	incr tnum
	}

	# This code tests that the storage classes specified above (in the $values
	# table) are correctly assigned when values are inserted using a statement
	# of the form:
	#
	# INSERT INTO t1 SELECT ....
	#
	set tnum 1
	foreach val $values {
	set lit [lindex $val 0]
	execsql "DELETE FROM t1;"
	execsql "INSERT INTO t1 SELECT $lit, $lit, $lit, $lit;"
	do_test types-1.2.$tnum {
	execsql {
	SELECT typeof(i), typeof(n), typeof(t), typeof(o) FROM t1;
	}
	} [lrange $val 1 end]
	incr tnum
	}

	# This code tests that the storage classes specified above (in the $values
	# table) are correctly assigned when values are inserted using a statement
	# of the form:
	#
	# UPDATE <table> SET <column> = <value>;
	#
	set tnum 1
	foreach val $values {
	set lit [lindex $val 0]
	execsql "UPDATE t1 SET i = $lit, n = $lit, t = $lit, o = $lit;"
	do_test types-1.3.$tnum {
	execsql {
	SELECT typeof(i), typeof(n), typeof(t), typeof(o) FROM t1;
	}
	} [lrange $val 1 end]
	incr tnum
	}

	execsql {
	DROP TABLE t1;
	}

	# Open the table with root-page $rootpage at the btree
	# level. Return a list that is the length of each record
	# in the table, in the tables default scanning order.
	proc record_sizes {rootpage} {
	set bt [btree_open test.db 10]
	btree_begin_transaction $bt
	set c [btree_cursor $bt $rootpage 0]
	btree_first $c
	while 1 {
	lappend res [btree_payload_size $c]
	if {[btree_next $c]} break
	}
	btree_close_cursor $c
	btree_close $bt
	set res
	}


	# Create a table and insert some 1-byte integers. Make sure they
	# can be read back OK. These should be 3 byte records.
	do_test types-2.1.1 {
	execsql {
	CREATE TABLE t1(a integer);
	INSERT INTO t1 VALUES(0);
	INSERT INTO t1 VALUES(120);
	INSERT INTO t1 VALUES(-120);
	}
	} {}
	do_test types-2.1.2 {
	execsql {
	SELECT a FROM t1;
	}
	} {0 120 -120}

	# Try some 2-byte integers (4 byte records)
	do_test types-2.1.3 {
	execsql {
	INSERT INTO t1 VALUES(30000);
	INSERT INTO t1 VALUES(-30000);
	}
	} {}
	do_test types-2.1.4 {
	execsql {
	SELECT a FROM t1;
	}
	} {0 120 -120 30000 -30000}

	# 4-byte integers (6 byte records)
	do_test types-2.1.5 {
	execsql {
	INSERT INTO t1 VALUES(2100000000);
	INSERT INTO t1 VALUES(-2100000000);
	}
	} {}
	do_test types-2.1.6 {
	execsql {
	SELECT a FROM t1;
	}
	} {0 120 -120 30000 -30000 2100000000 -2100000000}

	# 8-byte integers (10 byte records)
	do_test types-2.1.7 {
	execsql {
	INSERT INTO t1 VALUES(900000010000001000000);
	INSERT INTO t1 VALUES(-900000010000001000000);
	}
	} {}
	do_test types-2.1.8 {
	execsql {
	SELECT a FROM t1;
	}
	} [list 0 120 -120 30000 -30000 2100000000 -2100000000 \
	9000000000000000000 -9000000000000000000]

	# Check that all the record sizes are as we expected.
	ifcapable legacyformat {
	do_test types-2.1.9 {
	set root [db eval {select rootpage from sqlite_master where name = 't1'}]
	record_sizes $root
	} {3 3 3 4 4 6 6 10 10}
	} else {
	do_test types-2.1.9 {
	set root [db eval {select rootpage from sqlite_master where name = 't1'}]
	record_sizes $root
	} {2 3 3 4 4 6 6 10 10}
	}

	# Insert some reals. These should be 10 byte records.
	do_test types-2.2.1 {
	execsql {
	CREATE TABLE t2(a float);
	INSERT INTO t2 VALUES(0.0);
	INSERT INTO t2 VALUES(12345.678);
	INSERT INTO t2 VALUES(-12345.678);
	}
	} {}
	do_test types-2.2.2 {
	execsql {
	SELECT a FROM t2;
	}
	} {0.0 12345.678 -12345.678}

	# Check that all the record sizes are as we expected.
	ifcapable legacyformat {
	do_test types-2.2.3 {
	set root [db eval {select rootpage from sqlite_master where name = 't2'}]
	record_sizes $root
	} {3 10 10}
	} else {
	do_test types-2.2.3 {
	set root [db eval {select rootpage from sqlite_master where name = 't2'}]
	record_sizes $root
	} {2 10 10}
	}

	# Insert a NULL. This should be a two byte record.
	do_test types-2.3.1 {
	execsql {
	CREATE TABLE t3(a nullvalue);
	INSERT INTO t3 VALUES(NULL);
	}
	} {}
	do_test types-2.3.2 {
	execsql {
	SELECT a ISNULL FROM t3;
	}
	} {1}

	# Check that all the record sizes are as we expected.
	do_test types-2.3.3 {
	set root [db eval {select rootpage from sqlite_master where name = 't3'}]
	record_sizes $root
	} {2}

	# Insert a couple of strings.
	do_test types-2.4.1 {
	set string10 abcdefghij
	set string500 [string repeat $string10 50]
	set string500000 [string repeat $string10 50000]

	execsql "
	CREATE TABLE t4(a string);
	INSERT INTO t4 VALUES('$string10');
	INSERT INTO t4 VALUES('$string500');
	INSERT INTO t4 VALUES('$string500000');
	"
	} {}
	do_test types-2.4.2 {
	execsql {
	SELECT a FROM t4;
	}
	} [list $string10 $string500 $string500000]

	# Check that all the record sizes are as we expected. This is dependant on
	# the database encoding.
	if { $sqlite_options(utf16)==0 \|\| [execsql {pragma encoding}] == "UTF-8" } {
	do_test types-2.4.3 {
	set root [db eval {select rootpage from sqlite_master where name = 't4'}]
	record_sizes $root
	} {12 503 500004}
	} else {
	do_test types-2.4.3 {
	set root [db eval {select rootpage from sqlite_master where name = 't4'}]
	record_sizes $root
	} {22 1003 1000004}
	}

	do_test types-2.5.1 {
	execsql {
	DROP TABLE t1;
	DROP TABLE t2;
	DROP TABLE t3;
	DROP TABLE t4;
	CREATE TABLE t1(a, b, c);
	}
	} {}
	do_test types-2.5.2 {
	set string10 abcdefghij
	set string500 [string repeat $string10 50]
	set string500000 [string repeat $string10 50000]

	execsql "INSERT INTO t1 VALUES(NULL, '$string10', 4000);"
	execsql "INSERT INTO t1 VALUES('$string500', 4000, NULL);"
	execsql "INSERT INTO t1 VALUES(4000, NULL, '$string500000');"
	} {}
	do_test types-2.5.3 {
	execsql {
	SELECT * FROM t1;
	}
	} [list {} $string10 4000 $string500 4000 {} 4000 {} $string500000]

	finish_test