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# NOTE: this file tests how large files (>2GB) work with perlio (stdio/sfio).
# sysopen(), sysseek(), syswrite(), sysread() are tested in t/lib/syslfs.t.
# If you modify/add tests here, remember to update also ext/Fcntl/t/syslfs.t.
BEGIN {
chdir 't' if -d 't';
@INC = '../lib';
# Don't bother if there are no quad offsets.
require Config; import Config;
if ($Config{lseeksize} < 8) {
print "1..0 # Skip: no 64-bit file offsets\n";
exit(0);
}
}
use strict;
our @s;
our $fail;
sub zap {
close(BIG);
unlink("big");
unlink("big1");
unlink("big2");
}
sub bye {
zap();
exit(0);
}
my $explained;
sub explain {
unless ($explained++) {
print <<EOM;
#
# If the lfs (large file support: large meaning larger than two
# gigabytes) tests are skipped or fail, it may mean either that your
# process (or process group) is not allowed to write large files
# (resource limits) or that the file system (the network filesystem?)
# you are running the tests on doesn't let your user/group have large
# files (quota) or the filesystem simply doesn't support large files.
# You may even need to reconfigure your kernel. (This is all very
# operating system and site-dependent.)
#
# Perl may still be able to support large files, once you have
# such a process, enough quota, and such a (file) system.
# It is just that the test failed now.
#
EOM
}
print "1..0 # Skip: @_\n" if @_;
}
$| = 1;
print "# checking whether we have sparse files...\n";
# Known have-nots.
if ($^O eq 'MSWin32' || $^O eq 'NetWare' || $^O eq 'VMS') {
print "1..0 # Skip: no sparse files in $^O\n";
bye();
}
# Known haves that have problems running this test
# (for example because they do not support sparse files, like UNICOS)
if ($^O eq 'unicos') {
print "1..0 # Skip: no sparse files in $^O, unable to test large files\n";
bye();
}
# Then try to heuristically deduce whether we have sparse files.
# Let's not depend on Fcntl or any other extension.
my ($SEEK_SET, $SEEK_CUR, $SEEK_END) = (0, 1, 2);
# We'll start off by creating a one megabyte file which has
# only three "true" bytes. If we have sparseness, we should
# consume less blocks than one megabyte (assuming nobody has
# one megabyte blocks...)
open(BIG, ">big1") or
do { warn "open big1 failed: $!\n"; bye };
binmode(BIG) or
do { warn "binmode big1 failed: $!\n"; bye };
seek(BIG, 1_000_000, $SEEK_SET) or
do { warn "seek big1 failed: $!\n"; bye };
print BIG "big" or
do { warn "print big1 failed: $!\n"; bye };
close(BIG) or
do { warn "close big1 failed: $!\n"; bye };
my @s1 = stat("big1");
print "# s1 = @s1\n";
open(BIG, ">big2") or
do { warn "open big2 failed: $!\n"; bye };
binmode(BIG) or
do { warn "binmode big2 failed: $!\n"; bye };
seek(BIG, 2_000_000, $SEEK_SET) or
do { warn "seek big2 failed; $!\n"; bye };
print BIG "big" or
do { warn "print big2 failed; $!\n"; bye };
close(BIG) or
do { warn "close big2 failed; $!\n"; bye };
my @s2 = stat("big2");
print "# s2 = @s2\n";
zap();
unless ($s1[7] == 1_000_003 && $s2[7] == 2_000_003 &&
$s1[11] == $s2[11] && $s1[12] == $s2[12]) {
print "1..0 # Skip: no sparse files?\n";
bye;
}
print "# we seem to have sparse files...\n";
# By now we better be sure that we do have sparse files:
# if we are not, the following will hog 5 gigabytes of disk. Ooops.
# This may fail by producing some signal; run in a subprocess first for safety
$ENV{LC_ALL} = "C";
my $r = system '../perl', '-e', <<'EOF';
open(BIG, ">big");
seek(BIG, 5_000_000_000, 0);
print BIG "big";
exit 0;
EOF
open(BIG, ">big") or do { warn "open failed: $!\n"; bye };
binmode BIG;
if ($r or not seek(BIG, 5_000_000_000, $SEEK_SET)) {
my $err = $r ? 'signal '.($r & 0x7f) : $!;
explain("seeking past 2GB failed: $err");
bye();
}
# Either the print or (more likely, thanks to buffering) the close will
# fail if there are are filesize limitations (process or fs).
my $print = print BIG "big";
print "# print failed: $!\n" unless $print;
my $close = close BIG;
print "# close failed: $!\n" unless $close;
unless ($print && $close) {
if ($! =~/too large/i) {
explain("writing past 2GB failed: process limits?");
} elsif ($! =~ /quota/i) {
explain("filesystem quota limits?");
} else {
explain("error: $!");
}
bye();
}
@s = stat("big");
print "# @s\n";
unless ($s[7] == 5_000_000_003) {
explain("kernel/fs not configured to use large files?");
bye();
}
sub fail () {
print "not ";
$fail++;
}
sub offset ($$) {
my ($offset_will_be, $offset_want) = @_;
my $offset_is = eval $offset_will_be;
unless ($offset_is == $offset_want) {
print "# bad offset $offset_is, want $offset_want\n";
my ($offset_func) = ($offset_will_be =~ /^(\w+)/);
if (unpack("L", pack("L", $offset_want)) == $offset_is) {
print "# 32-bit wraparound suspected in $offset_func() since\n";
print "# $offset_want cast into 32 bits equals $offset_is.\n";
} elsif ($offset_want - unpack("L", pack("L", $offset_want)) - 1
== $offset_is) {
print "# 32-bit wraparound suspected in $offset_func() since\n";
printf "# %s - unpack('L', pack('L', %s)) - 1 equals %s.\n",
$offset_want,
$offset_want,
$offset_is;
}
fail;
}
}
print "1..17\n";
$fail = 0;
fail unless $s[7] == 5_000_000_003; # exercizes pp_stat
print "ok 1\n";
fail unless -s "big" == 5_000_000_003; # exercizes pp_ftsize
print "ok 2\n";
fail unless -e "big";
print "ok 3\n";
fail unless -f "big";
print "ok 4\n";
open(BIG, "big") or do { warn "open failed: $!\n"; bye };
binmode BIG;
fail unless seek(BIG, 4_500_000_000, $SEEK_SET);
print "ok 5\n";
offset('tell(BIG)', 4_500_000_000);
print "ok 6\n";
fail unless seek(BIG, 1, $SEEK_CUR);
print "ok 7\n";
# If you get 205_032_705 from here it means that
# your tell() is returning 32-bit values since (I32)4_500_000_001
# is exactly 205_032_705.
offset('tell(BIG)', 4_500_000_001);
print "ok 8\n";
fail unless seek(BIG, -1, $SEEK_CUR);
print "ok 9\n";
offset('tell(BIG)', 4_500_000_000);
print "ok 10\n";
fail unless seek(BIG, -3, $SEEK_END);
print "ok 11\n";
offset('tell(BIG)', 5_000_000_000);
print "ok 12\n";
my $big;
fail unless read(BIG, $big, 3) == 3;
print "ok 13\n";
fail unless $big eq "big";
print "ok 14\n";
# 705_032_704 = (I32)5_000_000_000
# See that we don't have "big" in the 705_... spot:
# that would mean that we have a wraparound.
fail unless seek(BIG, 705_032_704, $SEEK_SET);
print "ok 15\n";
my $zero;
fail unless read(BIG, $zero, 3) == 3;
print "ok 16\n";
fail unless $zero eq "\0\0\0";
print "ok 17\n";
explain() if $fail;
bye(); # does the necessary cleanup
END {
# unlink may fail if applied directly to a large file
# be paranoid about leaving 5 gig files lying around
open(BIG, ">big"); # truncate
close(BIG);
1 while unlink "big"; # standard portable idiom
}
# eof
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