package FileSlurp_12; use strict; use Carp ; use Fcntl qw( :DEFAULT ) ; use POSIX qw( :fcntl_h ) ; use Symbol ; use base 'Exporter' ; use vars qw( %EXPORT_TAGS @EXPORT_OK $VERSION @EXPORT ) ; %EXPORT_TAGS = ( 'all' => [ qw( read_file write_file overwrite_file append_file read_dir ) ] ) ; @EXPORT = ( @{ $EXPORT_TAGS{'all'} } ); @EXPORT_OK = qw( slurp ) ; $VERSION = '9999.13'; my $is_win32 = $^O =~ /win32/i ; # Install subs for various constants that aren't set in older perls # (< 5.005). Fcntl on old perls uses Exporter to define subs without a # () prototype These can't be overridden with the constant pragma or # we get a prototype mismatch. Hence this less than aesthetically # appealing BEGIN block: BEGIN { unless( eval { defined SEEK_SET() } ) { *SEEK_SET = sub { 0 }; *SEEK_CUR = sub { 1 }; *SEEK_END = sub { 2 }; } unless( eval { defined O_BINARY() } ) { *O_BINARY = sub { 0 }; *O_RDONLY = sub { 0 }; *O_WRONLY = sub { 1 }; } unless ( eval { defined O_APPEND() } ) { if ( $^O =~ /olaris/ ) { *O_APPEND = sub { 8 }; *O_CREAT = sub { 256 }; *O_EXCL = sub { 1024 }; } elsif ( $^O =~ /inux/ ) { *O_APPEND = sub { 1024 }; *O_CREAT = sub { 64 }; *O_EXCL = sub { 128 }; } elsif ( $^O =~ /BSD/i ) { *O_APPEND = sub { 8 }; *O_CREAT = sub { 512 }; *O_EXCL = sub { 2048 }; } } } # print "OS [$^O]\n" ; # print "O_BINARY = ", O_BINARY(), "\n" ; # print "O_RDONLY = ", O_RDONLY(), "\n" ; # print "O_WRONLY = ", O_WRONLY(), "\n" ; # print "O_APPEND = ", O_APPEND(), "\n" ; # print "O_CREAT ", O_CREAT(), "\n" ; # print "O_EXCL ", O_EXCL(), "\n" ; *slurp = \&read_file ; sub read_file { my( $file_name, %args ) = @_ ; # set the buffer to either the passed in one or ours and init it to the null # string my $buf ; my $buf_ref = $args{'buf_ref'} || \$buf ; ${$buf_ref} = '' ; my( $read_fh, $size_left, $blk_size ) ; # check if we are reading from a handle (glob ref or IO:: object) if ( ref $file_name ) { # slurping a handle so use it and don't open anything. # set the block size so we know it is a handle and read that amount $read_fh = $file_name ; $blk_size = $args{'blk_size'} || 1024 * 1024 ; $size_left = $blk_size ; # DEEP DARK MAGIC. this checks the UNTAINT IO flag of a # glob/handle. only the DATA handle is untainted (since it is from # trusted data in the source file). this allows us to test if this is # the DATA handle and then to do a sysseek to make sure it gets # slurped correctly. on some systems, the buffered i/o pointer is not # left at the same place as the fd pointer. this sysseek makes them # the same so slurping with sysread will work. eval{ require B } ; if ( $@ ) { @_ = ( \%args, <IO->IoFLAGS & 16 ) { # set the seek position to the current tell. sysseek( $read_fh, tell( $read_fh ), SEEK_SET ) || croak "sysseek $!" ; } } else { # a regular file. set the sysopen mode my $mode = O_RDONLY ; $mode |= O_BINARY if $args{'binmode'} ; #printf "RD: BINARY %x MODE %x\n", O_BINARY, $mode ; # open the file and handle any error $read_fh = gensym ; unless ( sysopen( $read_fh, $file_name, $mode ) ) { @_ = ( \%args, "read_file '$file_name' - sysopen: $!"); goto &_error ; } # get the size of the file for use in the read loop $size_left = -s $read_fh ; unless( $size_left ) { $blk_size = $args{'blk_size'} || 1024 * 1024 ; $size_left = $blk_size ; } } # infinite read loop. we exit when we are done slurping while( 1 ) { # do the read and see how much we got my $read_cnt = sysread( $read_fh, ${$buf_ref}, $size_left, length ${$buf_ref} ) ; if ( defined $read_cnt ) { # good read. see if we hit EOF (nothing left to read) last if $read_cnt == 0 ; # loop if we are slurping a handle. we don't track $size_left then. next if $blk_size ; # count down how much we read and loop if we have more to read. $size_left -= $read_cnt ; last if $size_left <= 0 ; next ; } # handle the read error @_ = ( \%args, "read_file '$file_name' - sysread: $!"); goto &_error ; } # fix up cr/lf to be a newline if this is a windows text file ${$buf_ref} =~ s/\015\012/\n/g if $is_win32 && !$args{'binmode'} ; # this is the 5 returns in a row. each handles one possible # combination of caller context and requested return type my $sep = $/ ; $sep = '\n\n+' if defined $sep && $sep eq '' ; # caller wants to get an array ref of lines # this split doesn't work since it tries to use variable length lookbehind # the m// line works. # return [ split( m|(?<=$sep)|, ${$buf_ref} ) ] if $args{'array_ref'} ; return [ length(${$buf_ref}) ? ${$buf_ref} =~ /(.*?$sep|.+)/sg : () ] if $args{'array_ref'} ; # caller wants a list of lines (normal list context) # same problem with this split as before. # return split( m|(?<=$sep)|, ${$buf_ref} ) if wantarray ; return length(${$buf_ref}) ? ${$buf_ref} =~ /(.*?$sep|.+)/sg : () if wantarray ; # caller wants a scalar ref to the slurped text return $buf_ref if $args{'scalar_ref'} ; # caller wants a scalar with the slurped text (normal scalar context) return ${$buf_ref} if defined wantarray ; # caller passed in an i/o buffer by reference (normal void context) return ; } # error handling section # # all the error handling uses magic goto so the caller will get the # error message as if from their code and not this module. if we just # did a call on the error code, the carp/croak would report it from # this module since the error sub is one level down on the call stack # from read_file/write_file/read_dir. my %err_func = ( 'carp' => \&carp, 'croak' => \&croak, ) ; sub _error { my( $args, $err_msg ) = @_ ; # get the error function to use my $func = $err_func{ $args->{'err_mode'} || 'croak' } ; # if we didn't find it in our error function hash, they must have set # it to quiet and we don't do anything. return unless $func ; # call the carp/croak function $func->($err_msg) ; # return a hard undef (in list context this will be a single value of # undef which is not a legal in-band value) return undef ; } 1;