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NAME

       perlfilter - Source Filters

DESCRIPTION

       This article is about a little-known feature of Perl called source filters. Source filters
       alter the program text of a module before Perl sees it, much as a C preprocessor alters
       the source text of a C program before the compiler sees it. This article tells you more
       about what source filters are, how they work, and how to write your own.

       The original purpose of source filters was to let you encrypt your program source to
       prevent casual piracy. This isn't all they can do, as you'll soon learn. But first, the
       basics.

CONCEPTS

       Before the Perl interpreter can execute a Perl script, it must first read it from a file
       into memory for parsing and compilation. If that script itself includes other scripts with
       a "use" or "require" statement, then each of those scripts will have to be read from their
       respective files as well.

       Now think of each logical connection between the Perl parser and an individual file as a
       source stream. A source stream is created when the Perl parser opens a file, it continues
       to exist as the source code is read into memory, and it is destroyed when Perl is finished
       parsing the file. If the parser encounters a "require" or "use" statement in a source
       stream, a new and distinct stream is created just for that file.

       The diagram below represents a single source stream, with the flow of source from a Perl
       script file on the left into the Perl parser on the right. This is how Perl normally
       operates.

           file -------> parser

       There are two important points to remember:

       1.   Although there can be any number of source streams in existence at any given time,
            only one will be active.

       2.   Every source stream is associated with only one file.

       A source filter is a special kind of Perl module that intercepts and modifies a source
       stream before it reaches the parser. A source filter changes our diagram like this:

           file ----> filter ----> parser

       If that doesn't make much sense, consider the analogy of a command pipeline. Say you have
       a shell script stored in the compressed file trial.gz. The simple pipeline command below
       runs the script without needing to create a temporary file to hold the uncompressed file.

           gunzip -c trial.gz | sh

       In this case, the data flow from the pipeline can be represented as follows:

           trial.gz ----> gunzip ----> sh

       With source filters, you can store the text of your script compressed and use a source
       filter to uncompress it for Perl's parser:

            compressed           gunzip
           Perl program ---> source filter ---> parser

USING FILTERS

       So how do you use a source filter in a Perl script? Above, I said that a source filter is
       just a special kind of module. Like all Perl modules, a source filter is invoked with a
       use statement.

       Say you want to pass your Perl source through the C preprocessor before execution. As it
       happens, the source filters distribution comes with a C preprocessor filter module called
       Filter::cpp.

       Below is an example program, "cpp_test", which makes use of this filter.  Line numbers
       have been added to allow specific lines to be referenced easily.

           1: use Filter::cpp;
           2: #define TRUE 1
           3: $a = TRUE;
           4: print "a = $a\n";

       When you execute this script, Perl creates a source stream for the file. Before the parser
       processes any of the lines from the file, the source stream looks like this:

           cpp_test ---------> parser

       Line 1, "use Filter::cpp", includes and installs the "cpp" filter module. All source
       filters work this way. The use statement is compiled and executed at compile time, before
       any more of the file is read, and it attaches the cpp filter to the source stream behind
       the scenes. Now the data flow looks like this:

           cpp_test ----> cpp filter ----> parser

       As the parser reads the second and subsequent lines from the source stream, it feeds those
       lines through the "cpp" source filter before processing them. The "cpp" filter simply
       passes each line through the real C preprocessor. The output from the C preprocessor is
       then inserted back into the source stream by the filter.

                         .-> cpp --.
                         |         |
                         |         |
                         |       <-'
          cpp_test ----> cpp filter ----> parser

       The parser then sees the following code:

           use Filter::cpp;
           $a = 1;
           print "a = $a\n";

       Let's consider what happens when the filtered code includes another module with use:

           1: use Filter::cpp;
           2: #define TRUE 1
           3: use Fred;
           4: $a = TRUE;
           5: print "a = $a\n";

       The "cpp" filter does not apply to the text of the Fred module, only to the text of the
       file that used it ("cpp_test"). Although the use statement on line 3 will pass through the
       cpp filter, the module that gets included ("Fred") will not. The source streams look like
       this after line 3 has been parsed and before line 4 is parsed:

           cpp_test ---> cpp filter ---> parser (INACTIVE)

           Fred.pm ----> parser

       As you can see, a new stream has been created for reading the source from "Fred.pm". This
       stream will remain active until all of "Fred.pm" has been parsed. The source stream for
       "cpp_test" will still exist, but is inactive. Once the parser has finished reading
       Fred.pm, the source stream associated with it will be destroyed. The source stream for
       "cpp_test" then becomes active again and the parser reads line 4 and subsequent lines from
       "cpp_test".

       You can use more than one source filter on a single file. Similarly, you can reuse the
       same filter in as many files as you like.

       For example, if you have a uuencoded and compressed source file, it is possible to stack a
       uudecode filter and an uncompression filter like this:

           use Filter::uudecode; use Filter::uncompress;
           M'XL(".H<US4''V9I;F%L')Q;>7/;1I;_>_I3=&E=%:F*I"T?22Q/
           M6]9*<IQCO*XFT"0[PL%%'Y+IG?WN^ZYN-$'J.[.JE$,20/?K=_[>
           ...

       Once the first line has been processed, the flow will look like this:

           file ---> uudecode ---> uncompress ---> parser
                      filter         filter

       Data flows through filters in the same order they appear in the source file. The uudecode
       filter appeared before the uncompress filter, so the source file will be uudecoded before
       it's uncompressed.

WRITING A SOURCE FILTER

       There are three ways to write your own source filter. You can write it in C, use an
       external program as a filter, or write the filter in Perl.  I won't cover the first two in
       any great detail, so I'll get them out of the way first. Writing the filter in Perl is
       most convenient, so I'll devote the most space to it.

WRITING A SOURCE FILTER IN C

       The first of the three available techniques is to write the filter completely in C. The
       external module you create interfaces directly with the source filter hooks provided by
       Perl.

       The advantage of this technique is that you have complete control over the implementation
       of your filter. The big disadvantage is the increased complexity required to write the
       filter - not only do you need to understand the source filter hooks, but you also need a
       reasonable knowledge of Perl guts. One of the few times it is worth going to this trouble
       is when writing a source scrambler. The "decrypt" filter (which unscrambles the source
       before Perl parses it) included with the source filter distribution is an example of a C
       source filter (see Decryption Filters, below).

       Decryption Filters
            All decryption filters work on the principle of "security through obscurity."
            Regardless of how well you write a decryption filter and how strong your encryption
            algorithm is, anyone determined enough can retrieve the original source code. The
            reason is quite simple - once the decryption filter has decrypted the source back to
            its original form, fragments of it will be stored in the computer's memory as Perl
            parses it. The source might only be in memory for a short period of time, but anyone
            possessing a debugger, skill, and lots of patience can eventually reconstruct your
            program.

            That said, there are a number of steps that can be taken to make life difficult for
            the potential cracker. The most important: Write your decryption filter in C and
            statically link the decryption module into the Perl binary. For further tips to make
            life difficult for the potential cracker, see the file decrypt.pm in the source
            filters distribution.

CREATING A SOURCE FILTER AS A SEPARATE EXECUTABLE

       An alternative to writing the filter in C is to create a separate executable in the
       language of your choice. The separate executable reads from standard input, does whatever
       processing is necessary, and writes the filtered data to standard output. "Filter::cpp" is
       an example of a source filter implemented as a separate executable - the executable is the
       C preprocessor bundled with your C compiler.

       The source filter distribution includes two modules that simplify this task:
       "Filter::exec" and "Filter::sh". Both allow you to run any external executable. Both use a
       coprocess to control the flow of data into and out of the external executable. (For
       details on coprocesses, see Stephens, W.R., "Advanced Programming in the UNIX
       Environment."  Addison-Wesley, ISBN 0-210-56317-7, pages 441-445.) The difference between
       them is that "Filter::exec" spawns the external command directly, while "Filter::sh"
       spawns a shell to execute the external command. (Unix uses the Bourne shell; NT uses the
       cmd shell.) Spawning a shell allows you to make use of the shell metacharacters and
       redirection facilities.

       Here is an example script that uses "Filter::sh":

           use Filter::sh 'tr XYZ PQR';
           $a = 1;
           print "XYZ a = $a\n";

       The output you'll get when the script is executed:

           PQR a = 1

       Writing a source filter as a separate executable works fine, but a small performance
       penalty is incurred. For example, if you execute the small example above, a separate
       subprocess will be created to run the Unix "tr" command. Each use of the filter requires
       its own subprocess.  If creating subprocesses is expensive on your system, you might want
       to consider one of the other options for creating source filters.

WRITING A SOURCE FILTER IN PERL

       The easiest and most portable option available for creating your own source filter is to
       write it completely in Perl. To distinguish this from the previous two techniques, I'll
       call it a Perl source filter.

       To help understand how to write a Perl source filter we need an example to study. Here is
       a complete source filter that performs rot13 decoding. (Rot13 is a very simple encryption
       scheme used in Usenet postings to hide the contents of offensive posts. It moves every
       letter forward thirteen places, so that A becomes N, B becomes O, and Z becomes M.)

          package Rot13;

          use Filter::Util::Call;

          sub import {
             my ($type) = @_;
             my ($ref) = [];
             filter_add(bless $ref);
          }

          sub filter {
             my ($self) = @_;
             my ($status);

             tr/n-za-mN-ZA-M/a-zA-Z/
                if ($status = filter_read()) > 0;
             $status;
          }

          1;

       All Perl source filters are implemented as Perl classes and have the same basic structure
       as the example above.

       First, we include the "Filter::Util::Call" module, which exports a number of functions
       into your filter's namespace. The filter shown above uses two of these functions,
       "filter_add()" and "filter_read()".

       Next, we create the filter object and associate it with the source stream by defining the
       "import" function. If you know Perl well enough, you know that "import" is called
       automatically every time a module is included with a use statement. This makes "import"
       the ideal place to both create and install a filter object.

       In the example filter, the object ($ref) is blessed just like any other Perl object. Our
       example uses an anonymous array, but this isn't a requirement. Because this example
       doesn't need to store any context information, we could have used a scalar or hash
       reference just as well. The next section demonstrates context data.

       The association between the filter object and the source stream is made with the
       "filter_add()" function. This takes a filter object as a parameter ($ref in this case) and
       installs it in the source stream.

       Finally, there is the code that actually does the filtering. For this type of Perl source
       filter, all the filtering is done in a method called "filter()". (It is also possible to
       write a Perl source filter using a closure. See the "Filter::Util::Call" manual page for
       more details.) It's called every time the Perl parser needs another line of source to
       process. The "filter()" method, in turn, reads lines from the source stream using the
       "filter_read()" function.

       If a line was available from the source stream, "filter_read()" returns a status value
       greater than zero and appends the line to $_.  A status value of zero indicates end-of-
       file, less than zero means an error. The filter function itself is expected to return its
       status in the same way, and put the filtered line it wants written to the source stream in
       $_. The use of $_ accounts for the brevity of most Perl source filters.

       In order to make use of the rot13 filter we need some way of encoding the source file in
       rot13 format. The script below, "mkrot13", does just that.

           die "usage mkrot13 filename\n" unless @ARGV;
           my $in = $ARGV[0];
           my $out = "$in.tmp";
           open(IN, "<$in") or die "Cannot open file $in: $!\n";
           open(OUT, ">$out") or die "Cannot open file $out: $!\n";

           print OUT "use Rot13;\n";
           while (<IN>) {
              tr/a-zA-Z/n-za-mN-ZA-M/;
              print OUT;
           }

           close IN;
           close OUT;
           unlink $in;
           rename $out, $in;

       If we encrypt this with "mkrot13":

           print " hello fred \n";

       the result will be this:

           use Rot13;
           cevag "uryyb serq\a";

       Running it produces this output:

           hello fred

USING CONTEXT: THE DEBUG FILTER

       The rot13 example was a trivial example. Here's another demonstration that shows off a few
       more features.

       Say you wanted to include a lot of debugging code in your Perl script during development,
       but you didn't want it available in the released product. Source filters offer a solution.
       In order to keep the example simple, let's say you wanted the debugging output to be
       controlled by an environment variable, "DEBUG". Debugging code is enabled if the variable
       exists, otherwise it is disabled.

       Two special marker lines will bracket debugging code, like this:

           ## DEBUG_BEGIN
           if ($year > 1999) {
              warn "Debug: millennium bug in year $year\n";
           }
           ## DEBUG_END

       The filter ensures that Perl parses the code between the <DEBUG_BEGIN> and "DEBUG_END"
       markers only when the "DEBUG" environment variable exists. That means that when "DEBUG"
       does exist, the code above should be passed through the filter unchanged. The marker lines
       can also be passed through as-is, because the Perl parser will see them as comment lines.
       When "DEBUG" isn't set, we need a way to disable the debug code. A simple way to achieve
       that is to convert the lines between the two markers into comments:

           ## DEBUG_BEGIN
           #if ($year > 1999) {
           #     warn "Debug: millennium bug in year $year\n";
           #}
           ## DEBUG_END

       Here is the complete Debug filter:

           package Debug;

           use v5.36;
           use Filter::Util::Call;

           use constant TRUE => 1;
           use constant FALSE => 0;

           sub import {
              my ($type) = @_;
              my (%context) = (
                Enabled => defined $ENV{DEBUG},
                InTraceBlock => FALSE,
                Filename => (caller)[1],
                LineNo => 0,
                LastBegin => 0,
              );
              filter_add(bless \%context);
           }

           sub Die {
              my ($self) = shift;
              my ($message) = shift;
              my ($line_no) = shift || $self->{LastBegin};
              die "$message at $self->{Filename} line $line_no.\n"
           }

           sub filter {
              my ($self) = @_;
              my ($status);
              $status = filter_read();
              ++ $self->{LineNo};

              # deal with EOF/error first
              if ($status <= 0) {
                  $self->Die("DEBUG_BEGIN has no DEBUG_END")
                      if $self->{InTraceBlock};
                  return $status;
              }

              if ($self->{InTraceBlock}) {
                 if (/^\s*##\s*DEBUG_BEGIN/ ) {
                     $self->Die("Nested DEBUG_BEGIN", $self->{LineNo})
                 } elsif (/^\s*##\s*DEBUG_END/) {
                     $self->{InTraceBlock} = FALSE;
                 }

                 # comment out the debug lines when the filter is disabled
                 s/^/#/ if ! $self->{Enabled};
              } elsif ( /^\s*##\s*DEBUG_BEGIN/ ) {
                 $self->{InTraceBlock} = TRUE;
                 $self->{LastBegin} = $self->{LineNo};
              } elsif ( /^\s*##\s*DEBUG_END/ ) {
                 $self->Die("DEBUG_END has no DEBUG_BEGIN", $self->{LineNo});
              }
              return $status;
           }

           1;

       The big difference between this filter and the previous example is the use of context data
       in the filter object. The filter object is based on a hash reference, and is used to keep
       various pieces of context information between calls to the filter function. All but two of
       the hash fields are used for error reporting. The first of those two, Enabled, is used by
       the filter to determine whether the debugging code should be given to the Perl parser. The
       second, InTraceBlock, is true when the filter has encountered a "DEBUG_BEGIN" line, but
       has not yet encountered the following "DEBUG_END" line.

       If you ignore all the error checking that most of the code does, the essence of the filter
       is as follows:

           sub filter {
              my ($self) = @_;
              my ($status);
              $status = filter_read();

              # deal with EOF/error first
              return $status if $status <= 0;
              if ($self->{InTraceBlock}) {
                 if (/^\s*##\s*DEBUG_END/) {
                    $self->{InTraceBlock} = FALSE
                 }

                 # comment out debug lines when the filter is disabled
                 s/^/#/ if ! $self->{Enabled};
              } elsif ( /^\s*##\s*DEBUG_BEGIN/ ) {
                 $self->{InTraceBlock} = TRUE;
              }
              return $status;
           }

       Be warned: just as the C-preprocessor doesn't know C, the Debug filter doesn't know Perl.
       It can be fooled quite easily:

           print <<EOM;
           ##DEBUG_BEGIN
           EOM

       Such things aside, you can see that a lot can be achieved with a modest amount of code.

CONCLUSION

       You now have better understanding of what a source filter is, and you might even have a
       possible use for them. If you feel like playing with source filters but need a bit of
       inspiration, here are some extra features you could add to the Debug filter.

       First, an easy one. Rather than having debugging code that is all-or-nothing, it would be
       much more useful to be able to control which specific blocks of debugging code get
       included. Try extending the syntax for debug blocks to allow each to be identified. The
       contents of the "DEBUG" environment variable can then be used to control which blocks get
       included.

       Once you can identify individual blocks, try allowing them to be nested. That isn't
       difficult either.

       Here is an interesting idea that doesn't involve the Debug filter.  Currently Perl
       subroutines have fairly limited support for formal parameter lists. You can specify the
       number of parameters and their type, but you still have to manually take them out of the
       @_ array yourself. Write a source filter that allows you to have a named parameter list.
       Such a filter would turn this:

           sub MySub ($first, $second, @rest) { ... }

       into this:

           sub MySub($$@) {
              my ($first) = shift;
              my ($second) = shift;
              my (@rest) = @_;
              ...
           }

       Finally, if you feel like a real challenge, have a go at writing a full-blown Perl macro
       preprocessor as a source filter. Borrow the useful features from the C preprocessor and
       any other macro processors you know. The tricky bit will be choosing how much knowledge of
       Perl's syntax you want your filter to have.

LIMITATIONS

       Source filters only work on the string level, thus are highly limited in its ability to
       change source code on the fly. It cannot detect comments, quoted strings, heredocs, it is
       no replacement for a real parser.  The only stable usage for source filters are
       encryption, compression, or the byteloader, to translate binary code back to source code.

       See for example the limitations in Switch, which uses source filters, and thus is does not
       work inside a string eval, the presence of regexes with embedded newlines that are
       specified with raw "/.../" delimiters and don't have a modifier "//x" are
       indistinguishable from code chunks beginning with the division operator "/". As a
       workaround you must use "m/.../" or "m?...?" for such patterns. Also, the presence of
       regexes specified with raw "?...?" delimiters may cause mysterious errors. The workaround
       is to use "m?...?" instead.  See <https://metacpan.org/pod/Switch#LIMITATIONS>.

       Currently the content of the "__DATA__" block is not filtered.

       Currently internal buffer lengths are limited to 32-bit only.

THINGS TO LOOK OUT FOR

       Some Filters Clobber the "DATA" Handle
            Some source filters use the "DATA" handle to read the calling program.  When using
            these source filters you cannot rely on this handle, nor expect any particular kind
            of behavior when operating on it.  Filters based on Filter::Util::Call (and therefore
            Filter::Simple) do not alter the "DATA" filehandle, but on the other hand totally
            ignore the text after "__DATA__".

REQUIREMENTS

       The Source Filters distribution is available on CPAN, in

           CPAN/modules/by-module/Filter

       Starting from Perl 5.8 Filter::Util::Call (the core part of the Source Filters
       distribution) is part of the standard Perl distribution.  Also included is a friendlier
       interface called Filter::Simple, by Damian Conway.

AUTHOR

       Paul Marquess <Paul.Marquess@btinternet.com>

       Reini Urban <rurban@cpan.org>

Copyrights

       The first version of this article originally appeared in The Perl Journal #11, and is
       copyright 1998 The Perl Journal. It appears courtesy of Jon Orwant and The Perl Journal.
       This document may be distributed under the same terms as Perl itself.