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Artifact cf679265ecafff494a768ac9c2f43a70915a6290:


# 2008 Feb 19
#
# 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.
#
#***********************************************************************
#
# The focus of this file is testing the r-tree extension.
#

if {![info exists testdir]} {
  set testdir [file join [file dirname [info script]] .. .. test]
}
source [file join [file dirname [info script]] rtree_util.tcl]
source $testdir/tester.tcl
set testprefix rtree1

# Test plan:
#
#   rtree-1.*: Creating/destroying r-tree tables.
#   rtree-2.*: Test the implicit constraints - unique rowid and
#              (coord[N]<=coord[N+1]) for even values of N. Also
#              automatic assigning of rowid values.
#   rtree-3.*: Linear scans of r-tree data.
#   rtree-4.*: Test INSERT
#   rtree-5.*: Test DELETE
#   rtree-6.*: Test UPDATE
#   rtree-7.*: Test renaming an r-tree table.
#   rtree-8.*: Test constrained scans of r-tree data.
#
#   rtree-12.*: Test that on-conflict clauses are supported.
#

ifcapable !rtree {
  finish_test
  return
}

#----------------------------------------------------------------------------
# Test cases rtree-1.* test CREATE and DROP table statements.
#

# Test creating and dropping an rtree table.
#
do_test rtree-1.1.1 {
  execsql { CREATE VIRTUAL TABLE t1 USING rtree(ii, x1, x2, y1, y2) }
} {}
do_test rtree-1.1.2 {
  execsql { SELECT name FROM sqlite_master ORDER BY name }
} {t1 t1_node t1_parent t1_rowid}
do_test rtree-1.1.3 {
  execsql { 
    DROP TABLE t1; 
    SELECT name FROM sqlite_master ORDER BY name;
  }
} {}

# Test creating and dropping an rtree table with an odd name in
# an attached database.
#
do_test rtree-1.2.1 {
  file delete -force test2.db
  execsql {
    ATTACH 'test2.db' AS aux;
    CREATE VIRTUAL TABLE aux.'a" "b' USING rtree(ii, x1, x2, y1, y2);
  }
} {}
do_test rtree-1.2.2 {
  execsql { SELECT name FROM sqlite_master ORDER BY name }
} {}
do_test rtree-1.2.3 {
  execsql { SELECT name FROM aux.sqlite_master ORDER BY name }
} {{a" "b} {a" "b_node} {a" "b_parent} {a" "b_rowid}}
do_test rtree-1.2.4 {
  execsql { 
    DROP TABLE aux.'a" "b'; 
    SELECT name FROM aux.sqlite_master ORDER BY name;
  }
} {}

# Test that the logic for checking the number of columns specified
# for an rtree table. Acceptable values are odd numbers between 3 and
# 11, inclusive.
#
set cols [list i1 i2 i3 i4 i5 i6 i7 i8 i9 iA iB iC iD iE iF iG iH iI iJ iK]
for {set nCol 1} {$nCol<[llength $cols]} {incr nCol} {

  set columns [join [lrange $cols 0 [expr {$nCol-1}]] ,]

  set X {0 {}}
  if {$nCol%2 == 0}  { set X {1 {Wrong number of columns for an rtree table}} }
  if {$nCol < 3}     { set X {1 {Too few columns for an rtree table}} }
  if {$nCol > 11}    { set X {1 {Too many columns for an rtree table}} }

  do_test rtree-1.3.$nCol {
    catchsql " 
      CREATE VIRTUAL TABLE t1 USING rtree($columns);
    "
  } $X

  catchsql { DROP TABLE t1 }
}

# Like execsql except display output as integer where that can be
# done without loss of information.
#
proc execsql_intout {sql} {
  set out {}
  foreach term [execsql $sql] {
    regsub {\.0$} $term {} term
    lappend out $term
  }
  return $out
}

# Test that it is possible to open an existing database that contains
# r-tree tables.
#
do_test rtree-1.4.1 {
  execsql {
    CREATE VIRTUAL TABLE t1 USING rtree(ii, x1, x2);
    INSERT INTO t1 VALUES(1, 5.0, 10.0);
    INSERT INTO t1 VALUES(2, 15.0, 20.0);
  }
} {}
do_test rtree-1.4.2 {
  db close
  sqlite3 db test.db
  execsql_intout { SELECT * FROM t1 ORDER BY ii }
} {1 5 10 2 15 20}
do_test rtree-1.4.3 {
  execsql { DROP TABLE t1 }
} {}

# Test that it is possible to create an r-tree table with ridiculous
# column names.
#
do_test rtree-1.5.1 {
  execsql_intout {
    CREATE VIRTUAL TABLE t1 USING rtree("the key", "x dim.", "x2'dim");
    INSERT INTO t1 VALUES(1, 2, 3);
    SELECT "the key", "x dim.", "x2'dim" FROM t1;
  }
} {1 2 3}
do_test rtree-1.5.1 {
  execsql { DROP TABLE t1 }
} {}

# Force the r-tree constructor to fail.
#
do_test rtree-1.6.1 {
  execsql { CREATE TABLE t1_rowid(a); }
  catchsql {
    CREATE VIRTUAL TABLE t1 USING rtree("the key", "x dim.", "x2'dim");
  }
} {1 {table "t1_rowid" already exists}}
do_test rtree-1.6.1 {
  execsql { DROP TABLE t1_rowid }
} {}

#----------------------------------------------------------------------------
# Test cases rtree-2.* 
#
do_test rtree-2.1.1 {
  execsql { 
    CREATE VIRTUAL TABLE t1 USING rtree(ii, x1, x2, y1, y2);
    SELECT * FROM t1;
  }
} {}

do_test rtree-2.1.2 {
  execsql { INSERT INTO t1 VALUES(NULL, 1, 3, 2, 4) }
  execsql_intout { SELECT * FROM t1 }
} {1 1 3 2 4}
do_test rtree-2.1.3 {
  execsql { INSERT INTO t1 VALUES(NULL, 1, 3, 2, 4) }
  execsql { SELECT rowid FROM t1 ORDER BY rowid }
} {1 2}
do_test rtree-2.1.3 {
  execsql { INSERT INTO t1 VALUES(NULL, 1, 3, 2, 4) }
  execsql { SELECT ii FROM t1 ORDER BY ii }
} {1 2 3}

do_test rtree-2.2.1 {
  catchsql { INSERT INTO t1 VALUES(2, 1, 3, 2, 4) }
} {1 {constraint failed}}
do_test rtree-2.2.2 {
  catchsql { INSERT INTO t1 VALUES(4, 1, 3, 4, 2) }
} {1 {constraint failed}}
do_test rtree-2.2.3 {
  catchsql { INSERT INTO t1 VALUES(4, 3, 1, 2, 4) }
} {1 {constraint failed}}
do_test rtree-2.2.4 {
  execsql { SELECT ii FROM t1 ORDER BY ii }
} {1 2 3}

do_test rtree-2.X {
  execsql { DROP TABLE t1 }
} {}

#----------------------------------------------------------------------------
# Test cases rtree-3.* test linear scans of r-tree table data. To test
# this we have to insert some data into an r-tree, but that is not the
# focus of these tests.
#
do_test rtree-3.1.1 {
  execsql { 
    CREATE VIRTUAL TABLE t1 USING rtree(ii, x1, x2, y1, y2);
    SELECT * FROM t1;
  }
} {}
do_test rtree-3.1.2 {
  execsql_intout { 
    INSERT INTO t1 VALUES(5, 1, 3, 2, 4);
    SELECT * FROM t1;
  }
} {5 1 3 2 4}
do_test rtree-3.1.3 {
  execsql_intout {
    INSERT INTO t1 VALUES(6, 2, 6, 4, 8);
    SELECT * FROM t1;
  }
} {5 1 3 2 4 6 2 6 4 8}

# Test the constraint on the coordinates (c[i]<=c[i+1] where (i%2==0)):
do_test rtree-3.2.1 {
  catchsql { INSERT INTO t1 VALUES(7, 2, 6, 4, 3) }
} {1 {constraint failed}}
do_test rtree-3.2.2 {
  catchsql { INSERT INTO t1 VALUES(8, 2, 6, 3, 3) }
} {0 {}}

#----------------------------------------------------------------------------
# Test cases rtree-5.* test DELETE operations.
#
do_test rtree-5.1.1 {
  execsql { CREATE VIRTUAL TABLE t2 USING rtree(ii, x1, x2) }
} {}
do_test rtree-5.1.2 {
  execsql_intout { 
    INSERT INTO t2 VALUES(1, 10, 20);
    INSERT INTO t2 VALUES(2, 30, 40);
    INSERT INTO t2 VALUES(3, 50, 60);
    SELECT * FROM t2 ORDER BY ii;
  }
} {1 10 20 2 30 40 3 50 60}
do_test rtree-5.1.3 {
  execsql_intout { 
    DELETE FROM t2 WHERE ii=2;
    SELECT * FROM t2 ORDER BY ii;
  }
} {1 10 20 3 50 60}
do_test rtree-5.1.4 {
  execsql_intout { 
    DELETE FROM t2 WHERE ii=1;
    SELECT * FROM t2 ORDER BY ii;
  }
} {3 50 60}
do_test rtree-5.1.5 {
  execsql { 
    DELETE FROM t2 WHERE ii=3;
    SELECT * FROM t2 ORDER BY ii;
  }
} {}
do_test rtree-5.1.6 {
  execsql { SELECT * FROM t2_rowid }
} {}

#----------------------------------------------------------------------------
# Test cases rtree-5.* test UPDATE operations.
#
do_test rtree-6.1.1 {
  execsql { CREATE VIRTUAL TABLE t3 USING rtree(ii, x1, x2, y1, y2) }
} {}
do_test rtree-6.1.2 {
  execsql_intout {
    INSERT INTO t3 VALUES(1, 2, 3, 4, 5);
    UPDATE t3 SET x2=5;
    SELECT * FROM t3;
  }
} {1 2 5 4 5}
do_test rtree-6.1.3 {
  execsql { UPDATE t3 SET ii = 2 }
  execsql_intout { SELECT * FROM t3 }
} {2 2 5 4 5}

#----------------------------------------------------------------------------
# Test cases rtree-7.* test rename operations.
#
do_test rtree-7.1.1 {
  execsql {
    CREATE VIRTUAL TABLE t4 USING rtree(ii, x1, x2, y1, y2, z1, z2);
    INSERT INTO t4 VALUES(1, 2, 3, 4, 5, 6, 7);
  }
} {}
do_test rtree-7.1.2 {
  execsql { ALTER TABLE t4 RENAME TO t5 }
  execsql_intout { SELECT * FROM t5 }
} {1 2 3 4 5 6 7}
do_test rtree-7.1.3 {
  db close
  sqlite3 db test.db
  execsql_intout { SELECT * FROM t5 }
} {1 2 3 4 5 6 7}
do_test rtree-7.1.4 {
  execsql { ALTER TABLE t5 RENAME TO 'raisara "one"'''}
  execsql_intout { SELECT * FROM "raisara ""one""'" }
} {1 2 3 4 5 6 7}
do_test rtree-7.1.5 {
  execsql_intout { SELECT * FROM 'raisara "one"''' }
} {1 2 3 4 5 6 7}
do_test rtree-7.1.6 {
  execsql { ALTER TABLE "raisara ""one""'" RENAME TO "abc 123" }
  execsql_intout { SELECT * FROM "abc 123" }
} {1 2 3 4 5 6 7}
do_test rtree-7.1.7 {
  db close
  sqlite3 db test.db
  execsql_intout { SELECT * FROM "abc 123" }
} {1 2 3 4 5 6 7}

# An error midway through a rename operation.
do_test rtree-7.2.1 {
  execsql { 
    CREATE TABLE t4_node(a);
  }
  catchsql { ALTER TABLE "abc 123" RENAME TO t4 }
} {1 {SQL logic error or missing database}}
do_test rtree-7.2.2 {
  execsql_intout { SELECT * FROM "abc 123" }
} {1 2 3 4 5 6 7}
do_test rtree-7.2.3 {
  execsql { 
    DROP TABLE t4_node;
    CREATE TABLE t4_rowid(a);
  }
  catchsql { ALTER TABLE "abc 123" RENAME TO t4 }
} {1 {SQL logic error or missing database}}
do_test rtree-7.2.4 {
  db close
  sqlite3 db test.db
  execsql_intout { SELECT * FROM "abc 123" }
} {1 2 3 4 5 6 7}
do_test rtree-7.2.5 {
  execsql { DROP TABLE t4_rowid }
  execsql { ALTER TABLE "abc 123" RENAME TO t4 }
  execsql_intout { SELECT * FROM t4 }
} {1 2 3 4 5 6 7}


#----------------------------------------------------------------------------
# Test cases rtree-8.*
#

# Test that the function to determine if a leaf cell is part of the
# result set works.
do_test rtree-8.1.1 {
  execsql {
    CREATE VIRTUAL TABLE t6 USING rtree(ii, x1, x2);
    INSERT INTO t6 VALUES(1, 3, 7);
    INSERT INTO t6 VALUES(2, 4, 6);
  }
} {}
do_test rtree-8.1.2 { execsql { SELECT ii FROM t6 WHERE x1>2 } } {1 2}
do_test rtree-8.1.3 { execsql { SELECT ii FROM t6 WHERE x1>3 } } {2}
do_test rtree-8.1.4 { execsql { SELECT ii FROM t6 WHERE x1>4 } } {}
do_test rtree-8.1.5 { execsql { SELECT ii FROM t6 WHERE x1>5 } } {}
do_test rtree-8.1.6 { execsql { SELECT ii FROM t6 WHERE x1<3 } } {}
do_test rtree-8.1.7 { execsql { SELECT ii FROM t6 WHERE x1<4 } } {1}
do_test rtree-8.1.8 { execsql { SELECT ii FROM t6 WHERE x1<5 } } {1 2}

#----------------------------------------------------------------------------
# Test cases rtree-9.*
#
# Test that ticket #3549 is fixed.
do_test rtree-9.1 {
  execsql {
    CREATE TABLE foo (id INTEGER PRIMARY KEY);
    CREATE VIRTUAL TABLE bar USING rtree (id, minX, maxX, minY, maxY);
    INSERT INTO foo VALUES (null);
    INSERT INTO foo SELECT null FROM foo;
    INSERT INTO foo SELECT null FROM foo;
    INSERT INTO foo SELECT null FROM foo;
    INSERT INTO foo SELECT null FROM foo;
    INSERT INTO foo SELECT null FROM foo;
    INSERT INTO foo SELECT null FROM foo;
    DELETE FROM foo WHERE id > 40;
    INSERT INTO bar SELECT NULL, 0, 0, 0, 0 FROM foo;
  }
} {}

# This used to crash.
do_test rtree-9.2 {
  execsql {
    SELECT count(*) FROM bar b1, bar b2, foo s1 WHERE s1.id = b1.id;
  }
} {1600}
do_test rtree-9.3 {
  execsql {
    SELECT count(*) FROM bar b1, bar b2, foo s1 
    WHERE b1.minX <= b2.maxX AND s1.id = b1.id;
  }
} {1600}

#-------------------------------------------------------------------------
# Ticket #3970: Check that the error message is meaningful when a 
# keyword is used as a column name.
#
do_test rtree-10.1 {
  catchsql { CREATE VIRTUAL TABLE t7 USING rtree(index, x1, y1, x2, y2) }
} {1 {near "index": syntax error}}

#-------------------------------------------------------------------------
# Test last_insert_rowid().
# 
do_test rtree-11.1 {
  execsql {
    CREATE VIRTUAL TABLE t8 USING rtree(idx, x1, x2, y1, y2);
    INSERT INTO t8 VALUES(1, 1.0, 1.0, 2.0, 2.0);
    SELECT last_insert_rowid();
  }
} {1}
do_test rtree-11.2 {
  execsql {
    INSERT INTO t8 VALUES(NULL, 1.0, 1.0, 2.0, 2.0);
    SELECT last_insert_rowid();
  }
} {2}

#-------------------------------------------------------------------------
# Test on-conflict clause handling.
#
db_delete_and_reopen
do_execsql_test 12.0 {
  CREATE VIRTUAL TABLE t1 USING rtree_i32(idx, x1, x2, y1, y2);
  INSERT INTO t1 VALUES(1,   1, 2, 3, 4);
  INSERT INTO t1 VALUES(2,   2, 3, 4, 5);
  INSERT INTO t1 VALUES(3,   3, 4, 5, 6);

  CREATE TABLE source(idx, x1, x2, y1, y2);
  INSERT INTO source VALUES(5, 8, 8, 8, 8);
  INSERT INTO source VALUES(2, 7, 7, 7, 7);
  
}
db_save_and_close
foreach {tn sql_template testdata} {
  1    "INSERT %CONF% INTO t1 VALUES(2, 7, 7, 7, 7)" {
    ROLLBACK 0 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6}
    ABORT    0 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7}
    IGNORE   0 0 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7}
    FAIL     0 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7}
    REPLACE  0 0 {1 1 2 3 4   2 7 7 7 7   3 3 4 5 6   4 4 5 6 7}
  }

  2    "INSERT %CONF% INTO t1 SELECT * FROM source" {
    ROLLBACK 1 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6}
    ABORT    1 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7}
    IGNORE   1 0 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7  5 8 8 8 8}
    FAIL     1 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7  5 8 8 8 8}
    REPLACE  1 0 {1 1 2 3 4   2 7 7 7 7   3 3 4 5 6   4 4 5 6 7  5 8 8 8 8}
  }

  3    "UPDATE %CONF% t1 SET idx = 2 WHERE idx = 4" {
    ROLLBACK 1 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6}
    ABORT    1 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7}
    IGNORE   1 0 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7}
    FAIL     1 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7}
    REPLACE  1 0 {1 1 2 3 4   2 4 5 6 7   3 3 4 5 6}
  }

  3    "UPDATE %CONF% t1 SET idx = ((idx+1)%5)+1 WHERE idx > 2" {
    ROLLBACK 1 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6}
    ABORT    1 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7}
    IGNORE   1 0 {1 1 2 3 4   2 2 3 4 5               4 4 5 6 7   5 3 4 5 6}
    FAIL     1 1 {1 1 2 3 4   2 2 3 4 5               4 4 5 6 7   5 3 4 5 6}
    REPLACE  1 0 {1 4 5 6 7   2 2 3 4 5                           5 3 4 5 6}
  }

  4    "INSERT %CONF% INTO t1 VALUES(2, 7, 6, 7, 7)" {
    ROLLBACK 0 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6}
    ABORT    0 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7}
    IGNORE   0 0 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7}
    FAIL     0 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7}
    REPLACE  0 1 {1 1 2 3 4   2 2 3 4 5   3 3 4 5 6   4 4 5 6 7}
  }

} {
  foreach {mode uses error data} $testdata {
    db_restore_and_reopen

    set sql [string map [list %CONF% "OR $mode"] $sql_template]
    set testname "12.$tn.[string tolower $mode]"

    execsql {
      BEGIN;
        INSERT INTO t1 VALUES(4,   4, 5, 6, 7);
    }

    set res(0) {0 {}}
    set res(1) {1 {constraint failed}}
    do_catchsql_test $testname.1 $sql $res($error)
    do_test $testname.2 [list sql_uses_stmt db $sql] $uses
    do_execsql_test $testname.3 { SELECT * FROM t1 ORDER BY idx } $data

    do_test $testname.4 { rtree_check db t1 } 0
    db close
  }
}
finish_test