Ubuntu Manpage: Sereal::Decoder - Fast, compact, powerful binary deserialization

Provided by: libsereal-decoder-perl_3.014-1build1_amd64

NAME

       Sereal::Decoder - Fast, compact, powerful binary deserialization

SYNOPSIS

         use Sereal::Decoder
           qw(decode_sereal sereal_decode_with_object scalar_looks_like_sereal);

         my $decoder = Sereal::Decoder->new({...options...});

         my $structure;
         $decoder->decode($blob, $structure); # deserializes into $structure

         # or if you don't have references to the top level structure, this works, too:
         $structure = $decoder->decode($blob);

         # alternatively functional interface: (See Sereal::Performance)
         sereal_decode_with_object($decoder, $blob, $structure);
         $structure = sereal_decode_with_object($decoder, $blob);

         # much slower functional interface with no persistent objects:
         decode_sereal($blob, {... options ...}, $structure);
         $structure = decode_sereal($blob, {... options ...});

         # Not a full validation, but just a quick check for a reasonable header:
         my $is_likely_sereal = scalar_looks_like_sereal($some_string);
         # or:
         $is_likely_sereal = $decoder->looks_like_sereal($some_string);

DESCRIPTION

       This library implements a deserializer for an efficient, compact-output, and feature-rich
       binary protocol called Sereal.  Its sister module Sereal::Encoder implements an encoder
       for this format.  The two are released separately to allow for independent and safer
       upgrading.

       The Sereal protocol versions that are compatible with this decoder implementation are
       currently protocol versions 1, 2, and 3. As it stands, it will refuse to attempt to decode
       future versions of the protocol, but if necessary there is likely going to be an option to
       decode the parts of the input that are compatible with version 3 of the protocol. The
       protocol was designed to allow for this.

       The protocol specification and many other bits of documentation can be found in the github
       repository. Right now, the specification is at
       <https://github.com/Sereal/Sereal/blob/master/sereal_spec.pod>, there is a discussion of
       the design objectives in <https://github.com/Sereal/Sereal/blob/master/README.pod>, and
       the output of our benchmarks can be seen at
       <https://github.com/Sereal/Sereal/wiki/Sereal-Comparison-Graphs>.

CLASS METHODS

new
Constructor. Optionally takes a hash reference as first parameter. This hash reference may
contain any number of options that influence the behaviour of the encoder.

Currently, the following options are recognized, none of them are on by default.

refuse_snappy

If set, the decoder will refuse Snappy-compressed input data. This can be desirable for
robustness. See the section "ROBUSTNESS" below.

refuse_objects

If set, the decoder will refuse deserializing any objects in the input stream and instead
throw and exception. Defaults to off. See the section "ROBUSTNESS" below.

no_bless_objects

If set, the decoder will deserialize any objects in the input stream but without blessing
them. Defaults to off. See the section "ROBUSTNESS" below.

validate_utf8

If set, the decoder will refuse invalid UTF-8 byte sequences. This is off by default, but
it's strongly encouraged to be turned on if you're dealing with any data that has been
encoded by an external source (e.g. http cookies).

max_recursion_depth

"Sereal::Decoder" is recursive. If you pass it a Sereal document that is deeply nested, it
will eventually exhaust the C stack. Therefore, there is a limit on the depth of recursion
that is accepted. It defaults to 10000 nested calls. You may choose to override this value
with the "max_recursion_depth" option. Beware that setting it too high can cause hard
crashes.

Do note that the setting is somewhat approximate. Setting it to 10000 may break at
somewhere between 9997 and 10003 nested structures depending on their types.

max_num_hash_entries

If set to a non-zero value (default: 0), then "Sereal::Decoder" will refuse to deserialize
any hash/dictionary (or hash-based object) with more than that number of entries. This is
to be able to respond quickly to any future hash-collision attacks on Perl's hash
function. Chances are, you don't want or need this. For a gentle introduction to the topic
from the cryptographic point of view, see <http://en.wikipedia.org/wiki/Collision_attack>.

incremental

If set to a non-zero value (default: 0), then "Sereal::Decoder" will destructively parse
Sereal documents out of a variable. Every time a Sereal document is successfully parsed it
is removed from the front of the string it is parsed from.

This means you can do this:

while (length $buffer) {
my $data= decode_sereal($buffer,{incremental=>1});
}

alias_smallint

If set to a true value then "Sereal::Decoder" will share integers from -16 to 15 (encoded
as either SRL_HDR_NEG and SRL_HDR_POS) as read-only aliases to a common SV.

The result of this may be significant space savings in data structures with many integers
in the specified range. The cost is more memory used by the decoder and a very modest
speed penalty when deserializing.

Note this option changes the structure of the dumped data. Use with caution.

See also the "alias_varint_under" option.

alias_varint_under

If set to a true positive integer smaller than 16 then this option is similar to setting
"alias_smallint" and causes all integers from -16 to 15 to be shared as read-only aliases
to the same SV, except that this treatment ALSO applies to SRL_HDR_VARINT. If set to a
value larger than 16 then this applies to all varints varints under the value set. (In
general SRL_HDR_VARINT is used only for integers larger than 15, and SRL_HDR_NEG and
SRL_HDR_POS are used for -16 to -1 and 0 to 15 respectively.)

In simple terms if you want to share values larger than 16 then you should use this
option, if you want to share only values in the -16 to 15 range then you should use the
"alias_smallint" option instead.

The result of this may be significant space savings in data structures with many integers
in the desire range. The cost is more memory used by the decoder and a very modest speed
penalty when deserializing.

Note this option changes the structure of the dumped data. Use with caution.

use_undef

If set to a true value then this any undef value to be deserialized as PL_sv_undef. This
may change the structure of the data structure being dumped, do not enable this unless you
know what you are doing.

set_readonly

If set to a true value then the output will be completely readonly (deeply).

set_readonly_scalars

If set to a true value then scalars in the output will be readonly (deeply). References
won't be readonly.

INSTANCE METHODS

   decode
       Given a byte string of Sereal data, the "decode" call deserializes that data structure.
       The result can be obtained in one of two ways: "decode" accepts a second parameter, which
       is a scalar to write the result to, AND "decode" will return the resulting data structure.

       The two are subtly different in case of data structures that contain references to the
       root element. In that case, the return value will be a (non-recursive) copy of the
       reference. The pass-in style is more correct.  In other words,

         $decoder->decode($sereal_string, my $out);
         # is almost the same but safer than:
         my $out = $decoder->decode($sereal_string);

       This is an unfortunate side-effect of perls standard copy semantics of assignment.
       Possibly one day we will have an alternative to this.

   decode_with_header
       Given a byte string of Sereal data, the "decode_with_header" call deserializes that data
       structure as "decode" would do, however it also decodes the optional user data structure
       that can be embedded into a Sereal document, inside the header  (see
       Sereal::Encoder::encode).

       It accepts an optional second parameter, which is a scalar to write the body to, and an
       optional third parameter, which is a scalar to write the header to.

       Regardless of the number of parameters received, "decode_with_header" returns an ArrayRef
       containing the deserialized body, and the deserialized header, in this order.

       See "decode" for the subtle difference between the one, two and three parameters versions.

       If there is no header in a Sereal document, corresponding variable or return value will be
       set to undef.

   decode_only_header
       Given a byte string of Sereal data, the "decode_only_header" deserializes only the
       optional user data structure that can be embedded into a Sereal document, inside the
       header (see Sereal::Encoder::encode).

       It accepts an optional second parameter, which is a scalar to write the header to.

       Regardless of the number of parameters received, "decode_only_header" returns the
       resulting data structure.

       See "decode" for the subtle difference between the one and two parameters versions.

       If there is no header in a Sereal document, corresponding variable or return value will be
       set to undef.

   decode_with_offset
       Same as the "decode" method, except as second parameter, you must pass an integer offset
       into the input string, at which the decoding is to start. The optional "pass-in" style
       scalar (see "decode" above) is relegated to being the third parameter.

   decode_only_header_with_offset
       Same as the "decode_only_header" method, except as second parameter, you must pass an
       integer offset into the input string, at which the decoding is to start. The optional
       "pass-in" style scalar (see "decode_only_header" above) is relegated to being the third
       parameter.

   decode_with_header_and_offset
       Same as the "decode_with_header" method, except as second parameter, you must pass an
       integer offset into the input string, at which the decoding is to start. The optional
       "pass-in" style scalars (see "decode_with_header" above) are relegated to being the third
       and fourth parameters.

   bytes_consumed
       After using the various "decode" methods documented previously, "bytes_consumed" can
       return the number of bytes from the body of the input string that were actually consumed
       by the decoder. That is, if you append random garbage to a valid Sereal document, "decode"
       will happily decode the data and ignore the garbage. If that is an error in your use case,
       you can use "bytes_consumed" to catch it.

         my $out = $decoder->decode($sereal_string);
         if (length($sereal_string) != $decoder->bytes_consumed) {
           die "Not all input data was consumed!";
         }

       Chances are that if you do this, you're violating UNIX philosophy in "be strict in what
       you emit but lenient in what you accept".

       You can also use this to deserialize a list of Sereal documents that is concatenated into
       the same string (code not very robust...):

         my @out;
         my $pos = 0;
         eval {
           while (1) {
             push @out, $decoder->decode_with_offset($sereal_string, $pos);
             $pos += $decoder->bytes_consumed;
             last if $pos >= length($sereal_string)
                  or not $decoder->bytes_consumed;
           }
         };

       As mentioned, only the bytes consumed from the body are considered. So the following
       example is correct, as only the header is deserialized:

         my $header = $decoder->decode_only_header($sereal_string);
         my $count = $decoder->bytes_consumed;
         # $count is 0

   looks_like_sereal
       Performs some rudimentary check to determine if the argument appears to be a valid Sereal
       packet or not. These tests are not comprehensive and a true result does not mean that the
       document is valid, merely that it appears to be valid. On the other hand a false result is
       always reliable.

       The return of this function may be treated as a simple boolean but is in fact a more
       complex return. When the argument does not look anything like a Sereal document then the
       return is perl's FALSE, which has the property of being string equivalent to "" and
       numerically equivalent to 0. However when the argument appears to be a UTF-8 encoded
       protocol 3 Sereal document (by noticing that the \xF3 in the magic string has been
       replaced by \xC3\xB3) then it returns 0 (the number, which is string equivalent to "0"),
       and otherwise returns the protocol version of the document. This means you can write
       something like this:

           $type= looks_like_sereal($thing);
           if ($type eq '') {
               say "Not a Sereal document";
           } elsif ($type eq '0') {
               say "Possibly utf8 encoded Sereal document";
           } else {
               say "Sereal document version $type";
           }

       For reference, Sereal's magic value is a four byte string which is either "=srl" for
       protocol version 1 and 2 or "=\xF3rl" for protocol version 3 and later. This function
       checks that the magic string corresponds with the reported version number, as well as
       other checks, which may be enhanced in the future.

EXPORTABLE FUNCTIONS

sereal_decode_with_object
The functional interface that is equivalent to using "decode". Takes a decoder object
reference as first parameter, followed by a byte string to deserialize. Optionally takes
a third parameter, which is the output scalar to write to. See the documentation for
"decode" above for details.

This functional interface is marginally faster than the OO interface since it avoids
method resolution overhead and, on sufficiently modern Perl versions, can usually avoid
subroutine call overhead. See Sereal::Performance for a discussion on how to tune Sereal
for maximum performance if you need to.

sereal_decode_with_header_with_object
The functional interface that is equivalent to using "decode_with_header". Takes a
decoder object reference as first parameter, followed by a byte string to deserialize.
Optionally takes third and fourth parameters, which are the output scalars to write to.
See the documentation for "decode_with_header" above for details.

sereal_decode_only_header_with_object
The functional interface that is equivalent to using "decode_only_header". Takes a
decoder object reference as first parameter, followed by a byte string to deserialize.
Optionally takes a third parameters, which outputs scalars to write to. See the
documentation for "decode_with_header" above for details.

sereal_decode_only_header_with_offset_with_object
The functional interface that is equivalent to using "decode_only_header_with_offset".
Same as the "sereal_decode_only_header_with_object" function, except as the third
parameter, you must pass an integer offset into the input string, at which the decoding is
to start. The optional "pass-in" style scalar (see "sereal_decode_only_header_with_object"
above) is relegated to being the fourth parameter.

sereal_decode_with_header_and_offset_with_object
The functional interface that is equivalent to using "decode_with_header_and_offset".
Same as the "sereal_decode_with_header_with_object" function, except as the third
parameter, you must pass an integer offset into the input string, at which the decoding is
to start. The optional "pass-in" style scalars (see
"sereal_decode_with_header_with_object" above) are relegated to being the fourth and fifth
parameters.

sereal_decode_with_offset_with_object
The functional interface that is equivalent to using "decode_with_offset". Same as the
"sereal_decode_with_object" function, except as the third parameter, you must pass an
integer offset into the input string, at which the decoding is to start. The optional
"pass-in" style scalar (see "sereal_decode_with_object" above) is relegated to being the
third parameter.

decode_sereal
The functional interface that is equivalent to using "new" and "decode". Expects a byte
string to deserialize as first argument, optionally followed by a hash reference of
options (see documentation for "new()"). Finally, "decode_sereal" supports a third
parameter, which is the output scalar to write to. See the documentation for "decode"
above for details.

This functional interface is significantly slower than the OO interface since it cannot
reuse the decoder object.

decode_sereal_with_header_data
The functional interface that is equivalent to using "new" and "decode_with_header".
Expects a byte string to deserialize as first argument, optionally followed by a hash
reference of options (see documentation for "new()"). Finally, "decode_sereal" supports
third and fourth parameters, which are the output scalars to write to. See the
documentation for "decode_with_header" above for details.

This functional interface is significantly slower than the OO interface since it cannot
reuse the decoder object.

scalar_looks_like_sereal
The functional interface that is equivalent to using "looks_like_sereal".

ROBUSTNESS

This implementation of a Sereal decoder tries to be as robust to invalid input data as
reasonably possible. This means that it should never (though read on) segfault. It may,
however, cause a large malloc to fail. Generally speaking, invalid data should cause a
Perl-trappable exception. The one exception is that for Snappy-compressed Sereal
documents, the Snappy library may cause segmentation faults (invalid reads or writes).
This should only be a problem if you do not checksum your data (internal checksum support
is a To-Do) or if you accept data from potentially malicious sources.

It requires a lot of run-time boundary checks to prevent decoder segmentation faults on
invalid data. We implemented them in the lightest way possible. Adding robustness against
running out of memory would cause an very significant run-time overhead. In most cases of
random garbage (with valid header no less) when a malloc() fails due to invalid data, the
problem was caused by a very large array or string length. This kind of very large malloc
can then fail, being trappable from Perl. Only when packet causes many repeated
allocations do you risk causing a hard OOM error from the kernel that cannot be trapped
because Perl may require some small allocations to succeed before the now-invalid memory
is released. It is at least not entirely trivial to craft a Sereal document that causes
this behaviour.

Finally, deserializing proper objects is potentially a problem because classes can define
a destructor. Thus, the data fed to the decoder can cause the (deferred) execution of any
destructor in your application. That's why the "refuse_objects" option exists and what
the "no_bless_objects" can be used for as well. Later on, we may or may not provide a
facility to whitelist classes. Furthermore, if the encoder emitted any objects using
"FREEZE" callbacks, the "THAW" class method may be invoked on the respective classes. If
you can't trust the source of your Sereal documents, you may want to use the
"refuse_objects" option. For more details on the "FREEZE/THAW" mechanism, please refer to
Sereal::Encoder.

PERFORMANCE

       Please refer to the Sereal::Performance document that has more detailed information about
       Sereal performance and tuning thereof.

THREAD-SAFETY

       "Sereal::Decoder" is thread-safe on Perl's 5.8.7 and higher. This means "thread-safe" in
       the sense that if you create a new thread, all "Sereal::Decoder" objects will become a
       reference to undef in the new thread. This might change in a future release to become a
       full clone of the decoder object.

BUGS, CONTACT AND SUPPORT

       For reporting bugs, please use the github bug tracker at
       <http://github.com/Sereal/Sereal/issues>.

       For support and discussion of Sereal, there are two Google Groups:

       Announcements around Sereal (extremely low volume):
       <https://groups.google.com/forum/?fromgroups#!forum/sereal-announce>

       Sereal development list: <https://groups.google.com/forum/?fromgroups#!forum/sereal-dev>

AUTHORS AND CONTRIBUTORS

       Yves Orton <demerphq@gmail.com>

       Damian Gryski

       Steffen Mueller <smueller@cpan.org>

       Rafaël Garcia-Suarez

       Ævar Arnfjörð Bjarmason <avar@cpan.org>

       Tim Bunce

       Daniel Dragan <bulkdd@cpan.org> (Windows support and bugfixes)

       Zefram

       Borislav Nikolov

       Ivan Kruglov <ivan.kruglov@yahoo.com>

       Eric Herman <eric@freesa.org>

       Some inspiration and code was taken from Marc Lehmann's excellent JSON::XS module due to
       obvious overlap in problem domain.

ACKNOWLEDGMENT

       This module was originally developed for Booking.com.  With approval from Booking.com,
       this module was generalized and published on CPAN, for which the authors would like to
       express their gratitude.

COPYRIGHT AND LICENSE

       Copyright (C) 2012, 2013, 2014 by Steffen Mueller Copyright (C) 2012, 2013, 2014 by Yves
       Orton

       The license for the code in this distribution is the following, with the exceptions listed
       below:

       This library is free software; you can redistribute it and/or modify it under the same
       terms as Perl itself.

       Except portions taken from Marc Lehmann's code for the JSON::XS module, which is licensed
       under the same terms as this module.  (Many thanks to Marc for inspiration, and code.)

       Also except the code for Snappy compression library, whose license is reproduced below and
       which, to the best of our knowledge, is compatible with this module's license. The license
       for the enclosed Snappy code is:

         Copyright 2011, Google Inc.
         All rights reserved.

         Redistribution and use in source and binary forms, with or without
         modification, are permitted provided that the following conditions are
         met:

           * Redistributions of source code must retain the above copyright
         notice, this list of conditions and the following disclaimer.
           * Redistributions in binary form must reproduce the above
         copyright notice, this list of conditions and the following disclaimer
         in the documentation and/or other materials provided with the
         distribution.
           * Neither the name of Google Inc. nor the names of its
         contributors may be used to endorse or promote products derived from
         this software without specific prior written permission.

         THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
         "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
         LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
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