#!./perl # If a read or write is interrupted by a signal, Perl will call the # signal handler and then attempt to restart the call. If the handler does # something nasty like close the handle or pop layers, make sure that the # read/write handles this gracefully (for some definition of 'graceful': # principally, don't segfault). BEGIN { chdir 't' if -d 't'; @INC = '../lib'; require './test.pl'; skip_all_without_dynamic_extension('Fcntl'); } use warnings; use strict; use Config; require './test.pl'; my $piped; eval { pipe my $in, my $out; $piped = 1; }; if (!$piped) { skip_all('pipe not implemented'); exit 0; } unless (exists $Config{'d_alarm'}) { skip_all('alarm not implemented'); exit 0; } # XXX for some reason the stdio layer doesn't seem to interrupt # write system call when the alarm triggers. This makes the tests # hang. if (exists $ENV{PERLIO} && $ENV{PERLIO} =~ /stdio/ ) { skip_all('stdio not supported for this script'); exit 0; } # on Win32, alarm() won't interrupt the read/write call. # Similar issues with VMS. # On FreeBSD, writes to pipes of 8192 bytes or more use a mechanism # that is not interruptible (see perl #85842 and #84688). # "close during print" also hangs on Solaris 8 (but not 10 or 11). # # Also skip on release builds, to avoid other possibly problematic # platforms my ($osmajmin) = $Config{osvers} =~ /^(\d+\.\d+)/; if ($^O eq 'VMS' || $^O eq 'MSWin32' || $^O eq 'cygwin' || $^O =~ /freebsd/ || $^O eq 'midnightbsd' || ($^O eq 'solaris' && $Config{osvers} eq '2.8') || $^O eq 'nto' || ($^O eq 'darwin' && $osmajmin < 9) || ((int($]*1000) & 1) == 0) ) { skip_all('various portability issues'); exit 0; } my ($in, $out, $st, $sigst, $buf); plan(tests => 10); # make two handles that will always block sub fresh_io { close $in if $in; close $out if $out; undef $in; undef $out; # use fresh handles each time pipe $in, $out; $sigst = ""; } $SIG{PIPE} = 'IGNORE'; # close during read fresh_io; $SIG{ALRM} = sub { $sigst = close($in) ? "ok" : "nok" }; alarm(1); $st = read($in, $buf, 1); alarm(0); is($sigst, 'ok', 'read/close: sig handler close status'); ok(!$st, 'read/close: read status'); ok(!close($in), 'read/close: close status'); # die during read fresh_io; $SIG{ALRM} = sub { die }; alarm(1); $st = eval { read($in, $buf, 1) }; alarm(0); ok(!$st, 'read/die: read status'); ok(close($in), 'read/die: close status'); # This used to be 1_000_000, but on Linux/ppc64 (POWER7) this kept # consistently failing. At exactly 0x100000 it started passing # again. Now we're asking the kernel what the pipe buffer is, and if # that fails, hoping this number is bigger than any pipe buffer. my $surely_this_arbitrary_number_is_fine = (eval { use Fcntl qw(F_GETPIPE_SZ); fcntl($out, F_GETPIPE_SZ, 0); } || 0xfffff) + 1; # close during print fresh_io; $SIG{ALRM} = sub { $sigst = close($out) ? "ok" : "nok" }; $buf = "a" x $surely_this_arbitrary_number_is_fine . "\n"; select $out; $| = 1; select STDOUT; alarm(1); $st = print $out $buf; alarm(0); is($sigst, 'nok', 'print/close: sig handler close status'); ok(!$st, 'print/close: print status'); ok(!close($out), 'print/close: close status'); # die during print fresh_io; $SIG{ALRM} = sub { die }; $buf = "a" x $surely_this_arbitrary_number_is_fine . "\n"; select $out; $| = 1; select STDOUT; alarm(1); $st = eval { print $out $buf }; alarm(0); ok(!$st, 'print/die: print status'); # the close will hang since there's data to flush, so use alarm alarm(1); ok(!eval {close($out)}, 'print/die: close status'); alarm(0); # close during close # Apparently there's nothing in standard Linux that can cause an # EINTR in close(2); but run the code below just in case it does on some # platform, just to see if it segfaults. fresh_io; $SIG{ALRM} = sub { $sigst = close($in) ? "ok" : "nok" }; alarm(1); close $in; alarm(0); # die during close fresh_io; $SIG{ALRM} = sub { die }; alarm(1); eval { close $in }; alarm(0); # vim: ts=4 sts=4 sw=4: