#!/usr/bin/perl
#
# Check ->defer and ->flush methods
#
# This is the old version, which you used in the past when
# there was a defer buffer separate from the read cache.
# There isn't any longer.
#
use POSIX 'SEEK_SET';
my $file = "tf$$.txt";
$: = Tie::File::_default_recsep();
my $data = "rec0$:rec1$:rec2$:";
my ($o, $n);
print "1..79\n";
my $N = 1;
use Tie::File;
print "ok $N\n"; $N++;
open F, "> $file" or die $!;
binmode F;
print F $data;
close F;
$o = tie @a, 'Tie::File', $file;
print $o ? "ok $N\n" : "not ok $N\n";
$N++;
# (3-6) Deferred storage
$o->defer;
$a[3] = "rec3";
check_contents($data); # nothing written yet
$a[4] = "rec4";
check_contents($data); # nothing written yet
# (7-8) Flush
$o->flush;
check_contents($data . "rec3$:rec4$:"); # now it's written
# (9-12) Deferred writing disabled?
$a[3] = "rec9";
check_contents("${data}rec9$:rec4$:");
$a[4] = "rec8";
check_contents("${data}rec9$:rec8$:");
# (13-18) Now let's try two batches of records
$#a = 2;
$o->defer;
$a[0] = "record0";
check_contents($data); # nothing written yet
$a[2] = "record2";
check_contents($data); # nothing written yet
$o->flush;
check_contents("record0$:rec1$:record2$:");
# (19-22) Deferred writing past the end of the file
$o->defer;
$a[4] = "record4";
check_contents("record0$:rec1$:record2$:");
$o->flush;
check_contents("record0$:rec1$:record2$:$:record4$:");
# (23-26) Now two long batches
$o->defer;
for (0..2, 4..6) {
$a[$_] = "r$_";
}
check_contents("record0$:rec1$:record2$:$:record4$:");
$o->flush;
check_contents(join $:, "r0".."r2", "", "r4".."r6", "");
# (27-30) Now let's make sure that discarded writes are really discarded
# We have a 2Mib buffer here, so we can be sure that we aren't accidentally
# filling it up
$o->defer;
for (0, 3, 7) {
$a[$_] = "discarded$_";
}
check_contents(join $:, "r0".."r2", "", "r4".."r6", "");
$o->discard;
check_contents(join $:, "r0".."r2", "", "r4".."r6", "");
################################################################
#
# Now we're going to test the results of a small memory limit
#
#
undef $o; untie @a;
$data = join "$:", map("record$_", 0..7), ""; # records are 8 or 9 bytes long
open F, "> $file" or die $!;
binmode F;
print F $data;
close F;
# Limit cache+buffer size to 47 bytes
my $MAX = 47;
# -- that's enough space for 5 records, but not 6, on both \n and \r\n systems
my $BUF = 20;
# -- that's enough space for 2 records, but not 3, on both \n and \r\n systems
$o = tie @a, 'Tie::File', $file, memory => $MAX, dw_size => $BUF;
print $o ? "ok $N\n" : "not ok $N\n";
$N++;
# (31-32) Fill up the read cache
my @z;
@z = @a;
# the cache now contains records 3,4,5,6,7.
check_caches({map(($_ => "record$_$:"), 3..7)},
{});
# (33-44) See if overloading the defer starts by flushing the read cache
# and then flushes out the defer
$o->defer;
$a[0] = "recordA"; # That should flush record 3 from the cache
check_caches({map(($_ => "record$_$:"), 4..7)},
{0 => "recordA$:"});
check_contents($data);
$a[1] = "recordB"; # That should flush record 4 from the cache
check_caches({map(($_ => "record$_$:"), 5..7)},
{0 => "recordA$:",
1 => "recordB$:"});
check_contents($data);
$a[2] = "recordC"; # That should flush the whole darn defer
# Flushing the defer requires looking up the true lengths of records
# 0..2, which flushes out the read cache, leaving only 1..2 there.
# Then the splicer updates the cached versions of 1..2 to contain the
# new data
check_caches({1 => "recordB$:", 2 => "recordC$:"},
{}); # URRRP
check_contents(join("$:", qw(recordA recordB recordC
record3 record4 record5 record6 record7)) . "$:");
$a[3] = "recordD"; # even though we flushed, deferring is STILL ENABLED
check_caches({1 => "recordB$:", 2 => "recordC$:"},
{3 => "recordD$:"});
check_contents(join("$:", qw(recordA recordB recordC
record3 record4 record5 record6 record7)) . "$:");
# Check readcache-deferbuffer interactions
# (45-47) This should remove outdated data from the read cache
$a[2] = "recordE";
check_caches({1 => "recordB$:", },
{3 => "recordD$:", 2 => "recordE$:"});
check_contents(join("$:", qw(recordA recordB recordC
record3 record4 record5 record6 record7)) . "$:");
# (48-51) This should read back out of the defer buffer
# without adding anything to the read cache
my $z;
$z = $a[2];
print $z eq "recordE" ? "ok $N\n" : "not ok $N\n"; $N++;
check_caches({1 => "recordB$:", },
{3 => "recordD$:", 2 => "recordE$:"});
check_contents(join("$:", qw(recordA recordB recordC
record3 record4 record5 record6 record7)) . "$:");
# (52-55) This should repopulate the read cache with a new record
$z = $a[0];
print $z eq "recordA" ? "ok $N\n" : "not ok $N\n"; $N++;
check_caches({1 => "recordB$:", 0 => "recordA$:"},
{3 => "recordD$:", 2 => "recordE$:"});
check_contents(join("$:", qw(recordA recordB recordC
record3 record4 record5 record6 record7)) . "$:");
# (56-59) This should flush the LRU record from the read cache
$z = $a[4]; $z = $a[5];
print $z eq "record5" ? "ok $N\n" : "not ok $N\n"; $N++;
check_caches({5 => "record5$:", 0 => "recordA$:", 4 => "record4$:"},
{3 => "recordD$:", 2 => "recordE$:"});
check_contents(join("$:", qw(recordA recordB recordC
record3 record4 record5 record6 record7)) . "$:");
# (60-63) This should FLUSH the deferred buffer
# In doing so, it will read in records 2 and 3, flushing 0 and 4
# from the read cache, leaving 2, 3, and 5.
$z = splice @a, 3, 1, "recordZ";
print $z eq "recordD" ? "ok $N\n" : "not ok $N\n"; $N++;
check_caches({5 => "record5$:", 3 => "recordZ$:", 2 => "recordE$:"},
{});
check_contents(join("$:", qw(recordA recordB recordE
recordZ record4 record5 record6 record7)) . "$:");
# (64-66) We should STILL be in deferred writing mode
$a[5] = "recordX";
check_caches({3 => "recordZ$:", 2 => "recordE$:"},
{5 => "recordX$:"});
check_contents(join("$:", qw(recordA recordB recordE
recordZ record4 record5 record6 record7)) . "$:");
# Fill up the defer buffer again
$a[4] = "recordP";
# (67-69) This should OVERWRITE the existing deferred record
# and NOT flush the buffer
$a[5] = "recordQ";
check_caches({3 => "recordZ$:", 2 => "recordE$:"},
{5 => "recordQ$:", 4 => "recordP$:"});
check_contents(join("$:", qw(recordA recordB recordE
recordZ record4 record5 record6 record7)) . "$:");
# (70-72) Discard should just dump the whole deferbuffer
$o->discard;
check_caches({3 => "recordZ$:", 2 => "recordE$:"},
{});
check_contents(join("$:", qw(recordA recordB recordE
recordZ record4 record5 record6 record7)) . "$:");
# (73-75) NOW we are out of deferred writing mode
$a[0] = "recordF";
check_caches({3 => "recordZ$:", 2 => "recordE$:", 0 => "recordF$:"},
{});
check_contents(join("$:", qw(recordF recordB recordE
recordZ record4 record5 record6 record7)) . "$:");
# (76-79) Last call--untying the array should flush the deferbuffer
$o->defer;
$a[0] = "flushed";
check_caches({3 => "recordZ$:", 2 => "recordE$:"},
{0 => "flushed$:" });
check_contents(join("$:", qw(recordF recordB recordE
recordZ record4 record5 record6 record7)) . "$:");
undef $o;
untie @a;
# (79) We can't use check_contents any more, because the object is dead
open F, "< $file" or die;
binmode F;
{ local $/ ; $z = <F> }
close F;
my $x = join("$:", qw(flushed recordB recordE
recordZ record4 record5 record6 record7)) . "$:";
if ($z eq $x) {
print "ok $N\n";
} else {
my $msg = ctrlfix("expected <$x>, got <$z>");
print "not ok $N \# $msg\n";
}
$N++;
################################################################
sub check_caches {
my ($xcache, $xdefer) = @_;
# my $integrity = $o->_check_integrity($file, $ENV{INTEGRITY});
# print $integrity ? "ok $N\n" : "not ok $N\n";
# $N++;
my $good = 1;
# Copy the contents of the cache into a regular hash
my %cache;
for my $k ($o->{cache}->ckeys) {
$cache{$k} = $o->{cache}->_produce($k);
}
$good &&= hash_equal(\%cache, $xcache, "true cache", "expected cache");
$good &&= hash_equal($o->{deferred}, $xdefer, "true defer", "expected defer");
print $good ? "ok $N\n" : "not ok $N\n";
$N++;
}
sub hash_equal {
my ($a, $b, $ha, $hb) = @_;
$ha = 'first hash' unless defined $ha;
$hb = 'second hash' unless defined $hb;
my $good = 1;
my %b_seen;
for my $k (keys %$a) {
if (! exists $b->{$k}) {
print ctrlfix("# Key $k is in $ha but not $hb"), "\n";
$good = 0;
} elsif ($b->{$k} ne $a->{$k}) {
print ctrlfix("# Key $k is <$a->{$k}> in $ha but <$b->{$k}> in $hb"), "\n";
$b_seen{$k} = 1;
$good = 0;
} else {
$b_seen{$k} = 1;
}
}
for my $k (keys %$b) {
unless ($b_seen{$k}) {
print ctrlfix("# Key $k is in $hb but not $ha"), "\n";
$good = 0;
}
}
$good;
}
sub check_contents {
my $x = shift;
my $integrity = $o->_check_integrity($file, $ENV{INTEGRITY});
print $integrity ? "ok $N\n" : "not ok $N\n";
$N++;
local *FH = $o->{fh};
seek FH, 0, SEEK_SET;
my $a;
{ local $/; $a = <FH> }
$a = "" unless defined $a;
if ($a eq $x) {
print "ok $N\n";
} else {
my $msg = ctrlfix("# expected <$x>, got <$a>");
print "not ok $N\n$msg\n";
}
$N++;
}
sub ctrlfix {
local $_ = shift;
s/\n/\\n/g;
s/\r/\\r/g;
$_;
}
END {
1 while unlink $file;
}
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