# 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 file is testing built-in functions. # # $Id: func.test,v 1.51 2006/03/26 01:21:23 drh Exp $ set testdir [file dirname $argv0] source $testdir/tester.tcl # Create a table to work with. # do_test func-0.0 { execsql {CREATE TABLE tbl1(t1 text)} foreach word {this program is free software} { execsql "INSERT INTO tbl1 VALUES('$word')" } execsql {SELECT t1 FROM tbl1 ORDER BY t1} } {free is program software this} do_test func-0.1 { execsql { CREATE TABLE t2(a); INSERT INTO t2 VALUES(1); INSERT INTO t2 VALUES(NULL); INSERT INTO t2 VALUES(345); INSERT INTO t2 VALUES(NULL); INSERT INTO t2 VALUES(67890); SELECT * FROM t2; } } {1 {} 345 {} 67890} # Check out the length() function # do_test func-1.0 { execsql {SELECT length(t1) FROM tbl1 ORDER BY t1} } {4 2 7 8 4} do_test func-1.1 { set r [catch {execsql {SELECT length(*) FROM tbl1 ORDER BY t1}} msg] lappend r $msg } {1 {wrong number of arguments to function length()}} do_test func-1.2 { set r [catch {execsql {SELECT length(t1,5) FROM tbl1 ORDER BY t1}} msg] lappend r $msg } {1 {wrong number of arguments to function length()}} do_test func-1.3 { execsql {SELECT length(t1), count(*) FROM tbl1 GROUP BY length(t1) ORDER BY length(t1)} } {2 1 4 2 7 1 8 1} do_test func-1.4 { execsql {SELECT coalesce(length(a),-1) FROM t2} } {1 -1 3 -1 5} # Check out the substr() function # do_test func-2.0 { execsql {SELECT substr(t1,1,2) FROM tbl1 ORDER BY t1} } {fr is pr so th} do_test func-2.1 { execsql {SELECT substr(t1,2,1) FROM tbl1 ORDER BY t1} } {r s r o h} do_test func-2.2 { execsql {SELECT substr(t1,3,3) FROM tbl1 ORDER BY t1} } {ee {} ogr ftw is} do_test func-2.3 { execsql {SELECT substr(t1,-1,1) FROM tbl1 ORDER BY t1} } {e s m e s} do_test func-2.4 { execsql {SELECT substr(t1,-1,2) FROM tbl1 ORDER BY t1} } {e s m e s} do_test func-2.5 { execsql {SELECT substr(t1,-2,1) FROM tbl1 ORDER BY t1} } {e i a r i} do_test func-2.6 { execsql {SELECT substr(t1,-2,2) FROM tbl1 ORDER BY t1} } {ee is am re is} do_test func-2.7 { execsql {SELECT substr(t1,-4,2) FROM tbl1 ORDER BY t1} } {fr {} gr wa th} do_test func-2.8 { execsql {SELECT t1 FROM tbl1 ORDER BY substr(t1,2,20)} } {this software free program is} do_test func-2.9 { execsql {SELECT substr(a,1,1) FROM t2} } {1 {} 3 {} 6} do_test func-2.10 { execsql {SELECT substr(a,2,2) FROM t2} } {{} {} 45 {} 78} # Only do the following tests if TCL has UTF-8 capabilities # if {"\u1234"!="u1234"} { # Put some UTF-8 characters in the database # do_test func-3.0 { execsql {DELETE FROM tbl1} foreach word "contains UTF-8 characters hi\u1234ho" { execsql "INSERT INTO tbl1 VALUES('$word')" } execsql {SELECT t1 FROM tbl1 ORDER BY t1} } "UTF-8 characters contains hi\u1234ho" do_test func-3.1 { execsql {SELECT length(t1) FROM tbl1 ORDER BY t1} } {5 10 8 5} do_test func-3.2 { execsql {SELECT substr(t1,1,2) FROM tbl1 ORDER BY t1} } {UT ch co hi} do_test func-3.3 { execsql {SELECT substr(t1,1,3) FROM tbl1 ORDER BY t1} } "UTF cha con hi\u1234" do_test func-3.4 { execsql {SELECT substr(t1,2,2) FROM tbl1 ORDER BY t1} } "TF ha on i\u1234" do_test func-3.5 { execsql {SELECT substr(t1,2,3) FROM tbl1 ORDER BY t1} } "TF- har ont i\u1234h" do_test func-3.6 { execsql {SELECT substr(t1,3,2) FROM tbl1 ORDER BY t1} } "F- ar nt \u1234h" do_test func-3.7 { execsql {SELECT substr(t1,4,2) FROM tbl1 ORDER BY t1} } "-8 ra ta ho" do_test func-3.8 { execsql {SELECT substr(t1,-1,1) FROM tbl1 ORDER BY t1} } "8 s s o" do_test func-3.9 { execsql {SELECT substr(t1,-3,2) FROM tbl1 ORDER BY t1} } "F- er in \u1234h" do_test func-3.10 { execsql {SELECT substr(t1,-4,3) FROM tbl1 ORDER BY t1} } "TF- ter ain i\u1234h" do_test func-3.99 { execsql {DELETE FROM tbl1} foreach word {this program is free software} { execsql "INSERT INTO tbl1 VALUES('$word')" } execsql {SELECT t1 FROM tbl1} } {this program is free software} } ;# End \u1234!=u1234 # Test the abs() and round() functions. # do_test func-4.1 { execsql { CREATE TABLE t1(a,b,c); INSERT INTO t1 VALUES(1,2,3); INSERT INTO t1 VALUES(2,1.2345678901234,-12345.67890); INSERT INTO t1 VALUES(3,-2,-5); } catchsql {SELECT abs(a,b) FROM t1} } {1 {wrong number of arguments to function abs()}} do_test func-4.2 { catchsql {SELECT abs() FROM t1} } {1 {wrong number of arguments to function abs()}} do_test func-4.3 { catchsql {SELECT abs(b) FROM t1 ORDER BY a} } {0 {2 1.2345678901234 2}} do_test func-4.4 { catchsql {SELECT abs(c) FROM t1 ORDER BY a} } {0 {3 12345.6789 5}} do_test func-4.4.1 { execsql {SELECT abs(a) FROM t2} } {1 {} 345 {} 67890} do_test func-4.4.2 { execsql {SELECT abs(t1) FROM tbl1} } {0.0 0.0 0.0 0.0 0.0} do_test func-4.5 { catchsql {SELECT round(a,b,c) FROM t1} } {1 {wrong number of arguments to function round()}} do_test func-4.6 { catchsql {SELECT round(b,2) FROM t1 ORDER BY b} } {0 {-2.0 1.23 2.0}} do_test func-4.7 { catchsql {SELECT round(b,0) FROM t1 ORDER BY a} } {0 {2.0 1.0 -2.0}} do_test func-4.8 { catchsql {SELECT round(c) FROM t1 ORDER BY a} } {0 {3.0 -12346.0 -5.0}} do_test func-4.9 { catchsql {SELECT round(c,a) FROM t1 ORDER BY a} } {0 {3.0 -12345.68 -5.0}} do_test func-4.10 { catchsql {SELECT 'x' || round(c,a) || 'y' FROM t1 ORDER BY a} } {0 {x3.0y x-12345.68y x-5.0y}} do_test func-4.11 { catchsql {SELECT round() FROM t1 ORDER BY a} } {1 {wrong number of arguments to function round()}} do_test func-4.12 { execsql {SELECT coalesce(round(a,2),'nil') FROM t2} } {1.0 nil 345.0 nil 67890.0} do_test func-4.13 { execsql {SELECT round(t1,2) FROM tbl1} } {0.0 0.0 0.0 0.0 0.0} do_test func-4.14 { execsql {SELECT typeof(round(5.1,1));} } {real} do_test func-4.15 { execsql {SELECT typeof(round(5.1));} } {real} # Test the upper() and lower() functions # do_test func-5.1 { execsql {SELECT upper(t1) FROM tbl1} } {THIS PROGRAM IS FREE SOFTWARE} do_test func-5.2 { execsql {SELECT lower(upper(t1)) FROM tbl1} } {this program is free software} do_test func-5.3 { execsql {SELECT upper(a), lower(a) FROM t2} } {1 1 {} {} 345 345 {} {} 67890 67890} do_test func-5.4 { catchsql {SELECT upper(a,5) FROM t2} } {1 {wrong number of arguments to function upper()}} do_test func-5.5 { catchsql {SELECT upper(*) FROM t2} } {1 {wrong number of arguments to function upper()}} # Test the coalesce() and nullif() functions # do_test func-6.1 { execsql {SELECT coalesce(a,'xyz') FROM t2} } {1 xyz 345 xyz 67890} do_test func-6.2 { execsql {SELECT coalesce(upper(a),'nil') FROM t2} } {1 nil 345 nil 67890} do_test func-6.3 { execsql {SELECT coalesce(nullif(1,1),'nil')} } {nil} do_test func-6.4 { execsql {SELECT coalesce(nullif(1,2),'nil')} } {1} do_test func-6.5 { execsql {SELECT coalesce(nullif(1,NULL),'nil')} } {1} # Test the last_insert_rowid() function # do_test func-7.1 { execsql {SELECT last_insert_rowid()} } [db last_insert_rowid] # Tests for aggregate functions and how they handle NULLs. # do_test func-8.1 { ifcapable explain { execsql {EXPLAIN SELECT sum(a) FROM t2;} } execsql { SELECT sum(a), count(a), round(avg(a),2), min(a), max(a), count(*) FROM t2; } } {68236 3 22745.33 1 67890 5} do_test func-8.2 { execsql { SELECT max('z+'||a||'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOP') FROM t2; } } {z+67890abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOP} ifcapable tempdb { do_test func-8.3 { execsql { CREATE TEMP TABLE t3 AS SELECT a FROM t2 ORDER BY a DESC; SELECT min('z+'||a||'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOP') FROM t3; } } {z+1abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOP} } else { do_test func-8.3 { execsql { CREATE TABLE t3 AS SELECT a FROM t2 ORDER BY a DESC; SELECT min('z+'||a||'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOP') FROM t3; } } {z+1abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOP} } do_test func-8.4 { execsql { SELECT max('z+'||a||'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOP') FROM t3; } } {z+67890abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOP} # How do you test the random() function in a meaningful, deterministic way? # do_test func-9.1 { execsql { SELECT random() is not null; } } {1} # Use the "sqlite_register_test_function" TCL command which is part of # the text fixture in order to verify correct operation of some of # the user-defined SQL function APIs that are not used by the built-in # functions. # set ::DB [sqlite3_connection_pointer db] sqlite_register_test_function $::DB testfunc do_test func-10.1 { catchsql { SELECT testfunc(NULL,NULL); } } {1 {first argument should be one of: int int64 string double null value}} do_test func-10.2 { execsql { SELECT testfunc( 'string', 'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ', 'int', 1234 ); } } {1234} do_test func-10.3 { execsql { SELECT testfunc( 'string', 'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ', 'string', NULL ); } } {{}} do_test func-10.4 { execsql { SELECT testfunc( 'string', 'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ', 'double', 1.234 ); } } {1.234} do_test func-10.5 { execsql { SELECT testfunc( 'string', 'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ', 'int', 1234, 'string', 'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ', 'string', NULL, 'string', 'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ', 'double', 1.234, 'string', 'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ', 'int', 1234, 'string', 'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ', 'string', NULL, 'string', 'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ', 'double', 1.234 ); } } {1.234} # Test the built-in sqlite_version(*) SQL function. # do_test func-11.1 { execsql { SELECT sqlite_version(*); } } [sqlite3 -version] # Test that destructors passed to sqlite3 by calls to sqlite3_result_text() # etc. are called. These tests use two special user-defined functions # (implemented in func.c) only available in test builds. # # Function test_destructor() takes one argument and returns a copy of the # text form of that argument. A destructor is associated with the return # value. Function test_destructor_count() returns the number of outstanding # destructor calls for values returned by test_destructor(). # do_test func-12.1 { execsql { SELECT test_destructor('hello world'), test_destructor_count(); } } {{hello world} 1} do_test func-12.2 { execsql { SELECT test_destructor_count(); } } {0} do_test func-12.3 { execsql { SELECT test_destructor('hello')||' world', test_destructor_count(); } } {{hello world} 0} do_test func-12.4 { execsql { SELECT test_destructor_count(); } } {0} do_test func-12.5 { execsql { CREATE TABLE t4(x); INSERT INTO t4 VALUES(test_destructor('hello')); INSERT INTO t4 VALUES(test_destructor('world')); SELECT min(test_destructor(x)), max(test_destructor(x)) FROM t4; } } {hello world} do_test func-12.6 { execsql { SELECT test_destructor_count(); } } {0} do_test func-12.7 { execsql { DROP TABLE t4; } } {} # Test that the auxdata API for scalar functions works. This test uses # a special user-defined function only available in test builds, # test_auxdata(). Function test_auxdata() takes any number of arguments. btree_breakpoint do_test func-13.1 { execsql { SELECT test_auxdata('hello world'); } } {0} do_test func-13.2 { execsql { CREATE TABLE t4(a, b); INSERT INTO t4 VALUES('abc', 'def'); INSERT INTO t4 VALUES('ghi', 'jkl'); } } {} do_test func-13.3 { execsql { SELECT test_auxdata('hello world') FROM t4; } } {0 1} do_test func-13.4 { execsql { SELECT test_auxdata('hello world', 123) FROM t4; } } {{0 0} {1 1}} do_test func-13.5 { execsql { SELECT test_auxdata('hello world', a) FROM t4; } } {{0 0} {1 0}} do_test func-13.6 { execsql { SELECT test_auxdata('hello'||'world', a) FROM t4; } } {{0 0} {1 0}} # Test that auxilary data is preserved between calls for SQL variables. do_test func-13.7 { set DB [sqlite3_connection_pointer db] set sql "SELECT test_auxdata( ? , a ) FROM t4;" set STMT [sqlite3_prepare $DB $sql -1 TAIL] sqlite3_bind_text $STMT 1 hello -1 set res [list] while { "SQLITE_ROW"==[sqlite3_step $STMT] } { lappend res [sqlite3_column_text $STMT 0] } lappend res [sqlite3_finalize $STMT] } {{0 0} {1 0} SQLITE_OK} # Make sure that a function with a very long name is rejected do_test func-14.1 { catch { db function [string repeat X 254] {return "hello"} } } {0} do_test func-14.2 { catch { db function [string repeat X 256] {return "hello"} } } {1} do_test func-15.1 { catchsql { select test_error(NULL); } } {1 {}} # Test the quote function for BLOB and NULL values. do_test func-16.1 { execsql { CREATE TABLE tbl2(a, b); } set STMT [sqlite3_prepare $::DB "INSERT INTO tbl2 VALUES(?, ?)" -1 TAIL] sqlite3_bind_blob $::STMT 1 abc 3 sqlite3_step $::STMT sqlite3_finalize $::STMT execsql { SELECT quote(a), quote(b) FROM tbl2; } } {X'616263' NULL} # Correctly handle function error messages that include %. Ticket #1354 # do_test func-17.1 { proc testfunc1 args {error "Error %d with %s percents %p"} db function testfunc1 ::testfunc1 catchsql { SELECT testfunc1(1,2,3); } } {1 {Error %d with %s percents %p}} # The SUM function should return integer results when all inputs are integer. # do_test func-18.1 { execsql { CREATE TABLE t5(x); INSERT INTO t5 VALUES(1); INSERT INTO t5 VALUES(-99); INSERT INTO t5 VALUES(10000); SELECT sum(x) FROM t5; } } {9902} do_test func-18.2 { execsql { INSERT INTO t5 VALUES(0.0); SELECT sum(x) FROM t5; } } {9902.0} # The sum of nothing is NULL. But the sum of all NULLs is NULL. # # The TOTAL of nothing is 0.0. # do_test func-18.3 { execsql { DELETE FROM t5; SELECT sum(x), total(x) FROM t5; } } {{} 0.0} do_test func-18.4 { execsql { INSERT INTO t5 VALUES(NULL); SELECT sum(x), total(x) FROM t5 } } {{} 0.0} do_test func-18.5 { execsql { INSERT INTO t5 VALUES(NULL); SELECT sum(x), total(x) FROM t5 } } {{} 0.0} do_test func-18.6 { execsql { INSERT INTO t5 VALUES(123); SELECT sum(x), total(x) FROM t5 } } {123 123.0} # Ticket #1664, #1669, #1670, #1674: An integer overflow on SUM causes # an error. The non-standard TOTAL() function continues to give a helpful # result. # do_test func-18.10 { execsql { CREATE TABLE t6(x INTEGER); INSERT INTO t6 VALUES(1); INSERT INTO t6 VALUES(1<<62); SELECT sum(x) - ((1<<62)+1) from t6; } } 0 do_test func-18.11 { execsql { SELECT typeof(sum(x)) FROM t6 } } integer do_test func-18.12 { catchsql { INSERT INTO t6 VALUES(1<<62); SELECT sum(x) - ((1<<62)*2.0+1) from t6; } } {1 {integer overflow}} do_test func-18.13 { execsql { SELECT total(x) - ((1<<62)*2.0+1) FROM t6 } } 0.0 do_test func-18.14 { execsql { SELECT sum(-9223372036854775805); } } -9223372036854775805 do_test func-18.15 { catchsql { SELECT sum(x) FROM (SELECT 9223372036854775807 AS x UNION ALL SELECT 10 AS x); } } {1 {integer overflow}} do_test func-18.16 { catchsql { SELECT sum(x) FROM (SELECT 9223372036854775807 AS x UNION ALL SELECT -10 AS x); } } {0 9223372036854775797} do_test func-18.17 { catchsql { SELECT sum(x) FROM (SELECT -9223372036854775807 AS x UNION ALL SELECT 10 AS x); } } {0 -9223372036854775797} do_test func-18.18 { catchsql { SELECT sum(x) FROM (SELECT -9223372036854775807 AS x UNION ALL SELECT -10 AS x); } } {1 {integer overflow}} do_test func-18.19 { catchsql { SELECT sum(x) FROM (SELECT 9 AS x UNION ALL SELECT -10 AS x); } } {0 -1} do_test func-18.20 { catchsql { SELECT sum(x) FROM (SELECT -9 AS x UNION ALL SELECT 10 AS x); } } {0 1} do_test func-18.21 { catchsql { SELECT sum(x) FROM (SELECT -10 AS x UNION ALL SELECT 9 AS x); } } {0 -1} do_test func-18.22 { catchsql { SELECT sum(x) FROM (SELECT 10 AS x UNION ALL SELECT -9 AS x); } } {0 1} # Integer overflow on abs() # do_test func-18.31 { catchsql { SELECT abs(-9223372036854775807); } } {0 9223372036854775807} do_test func-18.32 { catchsql { SELECT abs(-9223372036854775807-1); } } {1 {integer overflow}} finish_test