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Artifact 9f812fe1461b229020be9b8e4d0898b083a516b33db70892929129b9a35f45e8:


# 2013 March 20
#
# 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.
#
#***********************************************************************
#

set testdir [file dirname $argv0]
source $testdir/tester.tcl
ifcapable !mmap {
  finish_test
  return
}
source $testdir/lock_common.tcl
set testprefix mmap1

proc nRead {db} {
  set bt [btree_from_db $db]
  db_enter $db
  array set stats [btree_pager_stats $bt]
  db_leave $db
  # puts [array get stats]
  return $stats(read)
}

# Return a Tcl script that registers a user-defined scalar function 
# named rblob() with database handle $dbname. The function returns a
# sequence of pseudo-random blobs based on seed value $seed.
#
proc register_rblob_code {dbname seed} {
  return [subst -nocommands {
    set ::rcnt $seed
    proc rblob {n} {
      set ::rcnt [expr (([set ::rcnt] << 3) + [set ::rcnt] + 456) & 0xFFFFFFFF]
      set str [format %.8x [expr [set ::rcnt] ^ 0xbdf20da3]]
      string range [string repeat [set str] [expr [set n]/4]] 1 [set n]
    }
    $dbname func rblob rblob
  }]
}


# For cases 1.1 and 1.4, the number of pages read using xRead() is 4 on
# unix and 9 on windows. The difference is that windows only ever maps
# an integer number of OS pages (i.e. creates mappings that are a multiple
# of 4KB in size). Whereas on unix any sized mapping may be created.
#
foreach {t mmap_size nRead c2init} {
  1.1 { PRAGMA mmap_size = 67108864 } /[49]/ {PRAGMA mmap_size = 0}
  1.2 { PRAGMA mmap_size =    53248 } 150    {PRAGMA mmap_size = 0}
  1.3 { PRAGMA mmap_size =        0 } 344    {PRAGMA mmap_size = 0}
  1.4 { PRAGMA mmap_size = 67108864 } /[49]/ {PRAGMA mmap_size = 67108864 }
  1.5 { PRAGMA mmap_size =    53248 } 150    {PRAGMA mmap_size = 67108864 }
  1.6 { PRAGMA mmap_size =        0 } 344    {PRAGMA mmap_size = 67108864 }
} {

  do_multiclient_test tn {
    sql1 {PRAGMA cache_size=2000}
    sql2 {PRAGMA cache_size=2000}

    sql1 {PRAGMA page_size=1024}
    sql1 $mmap_size
    sql2 $c2init

    code2 [register_rblob_code db2 0]

    sql2 {
      PRAGMA page_size=1024;
      PRAGMA auto_vacuum = 1;
      CREATE TABLE t1(a, b, UNIQUE(a, b));
      INSERT INTO t1 VALUES(rblob(500), rblob(500));
      INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --    2
      INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --    4
      INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --    8
      INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --   16
      INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --   32
    }
    do_test $t.$tn.1 {
      sql1 "SELECT count(*) FROM t1; PRAGMA integrity_check ; PRAGMA page_count"
    } {32 ok 77}

    # Have connection 2 shrink the file. Check connection 1 can still read it.
    sql2 { DELETE FROM t1 WHERE rowid%2; }
    do_test $t.$tn.2 {
      sql1 "SELECT count(*) FROM t1; PRAGMA integrity_check ; PRAGMA page_count"
    } "16 ok [expr {42+[nonzero_reserved_bytes]}]"

    # Have connection 2 grow the file. Check connection 1 can still read it.
    sql2 { INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1 }
    do_test $t.$tn.3 {
      sql1 "SELECT count(*) FROM t1; PRAGMA integrity_check ; PRAGMA page_count"
    } {32 ok 79}

    # Have connection 2 grow the file again. Check connection 1 is still ok.
    sql2 { INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1 }
    do_test $t.$tn.4 {
      sql1 "SELECT count(*) FROM t1; PRAGMA integrity_check ; PRAGMA page_count"
    } {64 ok 149}

    # Check that the number of pages read by connection 1 indicates that the
    # "PRAGMA mmap_size" command worked.
    if {[nonzero_reserved_bytes]==0} {
      do_test $t.$tn.5 { nRead db } $nRead
    }
  }
}

set ::rcnt 0
proc rblob {n} {
  set ::rcnt [expr (($::rcnt << 3) + $::rcnt + 456) & 0xFFFFFFFF]
  set str [format %.8x [expr $::rcnt ^ 0xbdf20da3]]
  string range [string repeat $str [expr $n/4]] 1 $n
}

reset_db
db func rblob rblob

ifcapable wal {
  do_execsql_test 2.1 {
    PRAGMA auto_vacuum = 1;
    PRAGMA mmap_size = 67108864;
    PRAGMA journal_mode = wal;
    CREATE TABLE t1(a, b, UNIQUE(a, b));
    INSERT INTO t1 VALUES(rblob(500), rblob(500));
    INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --    2
    INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --    4
    INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --    8
    INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --   16
    INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --   32
    PRAGMA wal_checkpoint;
  } {67108864 wal 0 103 103}

  do_execsql_test 2.2 {
    PRAGMA auto_vacuum;
    SELECT count(*) FROM t1;
  } {1 32}

  if {[permutation] != "inmemory_journal"} {
    do_test 2.3 {
      sqlite3 db2 test.db
      db2 func rblob rblob
      db2 eval {
        DELETE FROM t1 WHERE (rowid%4);
          PRAGMA wal_checkpoint;
      }
      db2 eval {
        INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --    16
        SELECT count(*) FROM t1;
      }
    } {16}

    do_execsql_test 2.4 {
      PRAGMA wal_checkpoint;
    } {0 24 24}
    db2 close
  }
}

reset_db
execsql { PRAGMA mmap_size = 67108864; }
db func rblob rblob
do_execsql_test 3.1 {
  PRAGMA auto_vacuum = 1;

  CREATE TABLE t1(a, b, UNIQUE(a, b));
  INSERT INTO t1 VALUES(rblob(500), rblob(500));
  INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --    2
  INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --    4
  INSERT INTO t1 SELECT rblob(500), rblob(500) FROM t1; --    8

  CREATE TABLE t2(a, b, UNIQUE(a, b));
  INSERT INTO t2 SELECT * FROM t1;
} {}

do_test 3.2 {
  set nRow 0
  db eval {SELECT * FROM t2 ORDER BY a, b} {
    if {$nRow==4} { db eval { DELETE FROM t1 } }
    incr nRow
  }
  set nRow
} {8}

#-------------------------------------------------------------------------
# Ensure that existing cursors using xFetch() pages see changes made
# to rows using the incrblob API.
#
reset_db
execsql { PRAGMA mmap_size = 67108864; }
set aaa [string repeat a 400]
set bbb [string repeat b 400]
set ccc [string repeat c 400]
set ddd [string repeat d 400]
set eee [string repeat e 400]

do_execsql_test 4.1 {
  PRAGMA page_size = 1024;
  CREATE TABLE t1(x);
  INSERT INTO t1 VALUES($aaa);
  INSERT INTO t1 VALUES($bbb);
  INSERT INTO t1 VALUES($ccc);
  INSERT INTO t1 VALUES($ddd);
  SELECT * FROM t1;
  BEGIN;
} [list $aaa $bbb $ccc $ddd]

do_test 4.2 {
  set ::STMT [sqlite3_prepare db "SELECT * FROM t1 ORDER BY rowid" -1 dummy]
  sqlite3_step $::STMT
  sqlite3_column_text $::STMT 0
} $aaa

do_test 4.3 {
  foreach r {2 3 4} {
    set fd [db incrblob t1 x $r]
    puts -nonewline $fd $eee
    close $fd
  }

  set res [list]
  while {"SQLITE_ROW" == [sqlite3_step $::STMT]} {
    lappend res [sqlite3_column_text $::STMT 0]
  }
  set res
} [list $eee $eee $eee]

do_test 4.4 {
  sqlite3_finalize $::STMT
} SQLITE_OK

do_execsql_test 4.5 { COMMIT }

#-------------------------------------------------------------------------
# Ensure that existing cursors holding xFetch() references are not
# confused if those pages are moved to make way for the root page of a
# new table or index.
#
reset_db
execsql { PRAGMA mmap_size = 67108864; }
do_execsql_test 5.1 {
  PRAGMA auto_vacuum = 2;
  PRAGMA page_size = 1024;
  CREATE TABLE t1(x);
  INSERT INTO t1 VALUES($aaa);
  INSERT INTO t1 VALUES($bbb);
  INSERT INTO t1 VALUES($ccc);
  INSERT INTO t1 VALUES($ddd);

  PRAGMA auto_vacuum;
  SELECT * FROM t1;
} [list 2 $aaa $bbb $ccc $ddd]

do_test 5.2 {
  set ::STMT [sqlite3_prepare db "SELECT * FROM t1 ORDER BY rowid" -1 dummy]
  sqlite3_step $::STMT
  sqlite3_column_text $::STMT 0
} $aaa

do_execsql_test 5.3 {
  CREATE TABLE t2(x);
  INSERT INTO t2 VALUES('tricked you!');
  INSERT INTO t2 VALUES('tricked you!');
}

do_test 5.4 {
  sqlite3_step $::STMT
  sqlite3_column_text $::STMT 0
} $bbb

do_test 5.5 {
  sqlite3_finalize $::STMT
} SQLITE_OK

#
# The "6.*" tests are designed to test the interaction of mmap with file
# truncation (e.g. on Win32) via the VACUUM command.
#
forcedelete test2.db
sqlite3 db2 test2.db
do_test 6.0 {
  db2 eval {
    PRAGMA page_size = 4096;
  }
} {}
do_test 6.1 {
  db2 eval {
    CREATE TABLE t1(x);
    INSERT INTO t1(x) VALUES(randomblob(1000000));
  }
} {}
do_test 6.2 {
  db2 eval {
    PRAGMA mmap_size = 1048576;
  }
} {1048576}
do_test 6.3 {
  expr {[file size test2.db] > 1000000}
} {1}
do_test 6.4 {
  db2 eval {
    DELETE FROM t1;
  }
} {}
do_test 6.5 {
  expr {[file size test2.db] > 1000000}
} {1}
do_test 6.6 {
  db2 eval {
    VACUUM;
  }
} {}
do_test 6.7 {
  expr {[file size test2.db] < 1000000}
} {1}
db2 close

finish_test