NAME
XML::Compile::SOAP - base-class for SOAP implementations
INHERITANCE
XML::Compile::SOAP is extended by
XML::Compile::SOAP11
XML::Compile::SOAP12
SYNOPSIS
** SOAP1.1 and WSDL1.1 over HTTP
# !!! The next steps are only required when you do not have
# !!! a WSDL. See XML::Compile::WSDL11 if you have a WSDL.
# !!! Without WSDL file, you need to do a lot manually
use XML::Compile::SOAP11::Client;
my $client = XML::Compile::SOAP11::Client->new;
$client->schemas->importDefinitions(...);
use XML::Compile::Util qw/pack_type/;
my $h1el = pack_type $myns, $some_element;
my $b1el = "{$myns}$other_element"; # same, less clean
my $encode_query = $client->compileMessage
( 'SENDER'
, style => 'document' # default
, header => [ h1 => $h1el ]
, body => [ b1 => $b1el ]
, destination => [ h1 => 'NEXT' ]
, mustUnderstand => 'h1'
);
my $decode_response = $client->compileMessage
( 'RECEIVER'
, header => [ h2 => $h2el ]
, body => [ b2 => $b2el ]
, faults => [ ... ]
);
my $http = XML::Compile::Transport::SOAPHTTP
->new(address => $server);
my $http = $transport->compileClient(action => ...);
my @query = (h1 => ..., b1 => ...);
my $request = $encode_query->(@query);
my ($response, $trace) = $http->($request);
my $answer = $decode_response->($response);
use Data::Dumper;
warn Dumper $answer; # discover a HASH with h2 and b2!
if($answer->{Fault}) ... # when an error was reported
# Simplify your life: combine above into one call
# Also in this case: if you have a WSDL, this is created
# for you. $wsdl->compileClient('MyFirstCall');
my $call = $client->compileClient
( kind => 'request-response' # default
, name => 'MyFirstCall'
, encode => $encode_query
, decode => $decode_response
, transport => $http
);
# !!! Usage, with or without WSDL file the same
my $result = $call->(@quey) # SCALAR only the result
print $result->{h2}->{...};
print $result->{b2}->{...};
my ($result, $trace) = $call->(...); # LIST will show trace
# $trace is an XML::Compile::SOAP::Trace object
DESCRIPTION
This module handles the SOAP protocol. The first implementation is SOAP1.1 (http://www.w3.org/TR/2000/NOTE-SOAP-20000508/), which is still most often used. The SOAP1.2 definition (http://www.w3.org/TR/soap12/) is quite different; this module tries to define a sufficiently abstract interface to hide the protocol differences.
Be aware that there are three kinds of SOAP:
Document style (literal) SOAP, where there is a WSDL file which explicitly types all out-going and incoming messages. Very easy to use.
RPC style SOAP literal. The body of the message has an extra element wrapper, but the content is also well defined.
RPC style SOAP encoded. The sent data is nowhere described formally. The data is constructed in some ad-hoc way.
Don't forget to have a look at the examples in the examples/ directory included in the distribution.
METHODS
Constructors
$obj->new(OPTIONS)
Create a new SOAP object. You have to instantiate either the SOAP11 or SOAP12 sub-class of this, because there are quite some differences (which can be hidden for you)
Option --Default
media_type application/soap+xml
schemas created internally
. media_type => MIMETYPE
. schemas => XML::Compile::Cache
object
Use this when you have already processed some schema definitions. Otherwise, you can add schemas later with $soap->schemas->importDefinitions()
The Cache object must have any_element
and any_attribute
set to 'ATTEMPT'
Accessors
$obj->name
$obj->schemas
Returns the XML::Compile::Cache object which contains the knowledge about the types.
$obj->version
Single message
$obj->compileMessage(('SENDER'|'RECEIVER'), OPTIONS)
The payload is defined explicitly, where all headers and bodies are described in detail. When you have a WSDL file, these ENTRIES are generated automatically, but can be modified and extended (WSDL files are often incomplete)
To make your life easy, the ENTRIES use a label (a free to choose key, the part name in WSDL terminology), to ease relation of your data with the type where it belongs to. The element of an entry (the value) is defined as an any
element in the schema, and therefore you will need to explicitly specify the element to be processed.
As OPTIONS, you can specify any listed here, but also anything which is accepted by XML::Compile::Schema::compile(), like sloppy_integers => 1
and hooks. These are applied to all header and body elements (not to the SOAP wrappers)
Option --Default
body []
destination []
faults []
header undef
mustUnderstand []
role ULTIMATE
roles []
. body => ENTRIES|HASH
ARRAY of PAIRS, defining a nice LABEL (free of choice but unique, also w.r.t. the header and fault ENTRIES) and an element type name or CODE reference. The LABEL will appear in the Perl HASH only, to be able to refer to a body element in a simple way.
. destination => ARRAY-OF-PAIRS
Writers only. Indicate who the target of the header entry is. By default, the end-point is the destination of each header element.
The ARRAY contains a LIST of key-value pairs, specifing an entry label followed by an actor (soap1.1) or role (soap1.2) URI. You may use the predefined actors/roles, like 'NEXT'. See roleURI() and roleAbbreviation().
. faults => ENTRIES|HASH
The SOAP1.1 and SOAP1.2 protocols define fault entries in the answer. Both have a location to add your own additional information: the type(-processor) is to specified here, but the returned information structure is larger and differs per SOAP implementation.
. header => ENTRIES|HASH
ARRAY of PAIRS, defining a nice LABEL (free of choice but unique) and an element type name. The LABEL will appear in the Perl HASH, to refer to the element in a simple way.
The element type is used to construct a reader or writer. You may also create your own reader or writer, and then pass a compatible CODE reference.
. mustUnderstand => STRING|ARRAY-OF-STRING
Writers only. The specified header entry labels specify which elements must be understood by the destination. These elements will get the mustUnderstand
attribute set to 1
(soap1.1) or true
(soap1.2).
. role => URI|ARRAY-OF-URI
Readers only. One or more URIs, specifying the role(s) you application has in the process. Only when your role contains ULTIMATE
, the body is parsed. Otherwise, the body is returned as uninterpreted XML tree. You should not use the role NEXT
, because every intermediate node is a NEXT
.
All understood headers are parsed when the actor
(soap1.1) or role
(soap1.2) attribute address the specified URI. When other headers emerge which are not understood but carry the mustUnderstood
attribute, an fault is returned automatically. In that case, the call to the compiled subroutine will return undef
.
. roles => ARRAY-OF-URI
Alternative for option role
$obj->messageStructure(XML)
XML::Compile::SOAP->messageStructure(XML)
Returns a HASH with some collected information from a complete SOAP message (XML::LibXML::Document or XML::LibXML::Element). Currenty, the HASH contains a header
and a body
key, with each an ARRAY of element names which where found in the header resp. body.
Helpers
Transcoding
$obj->replyMustUnderstandFault(TYPE)
Produce an error structure to be returned to the sender.
$obj->roleAbbreviation(URI)
Translate a role URI into a simple string, if predefined. See roleURI().
$obj->roleURI(URI|STRING)
Translates actor/role/destination abbreviations into URIs. Various SOAP protocol versions have different pre-defined STRINGs, which can be abbreviated for readibility. Returns the unmodified URI in all other cases.
SOAP11 only defines NEXT
. SOAP12 defines NEXT
, NONE
, and ULTIMATE
.
DETAILS
SOAP introduction
Although the specification of SOAP1.1 and WSDL1.1 are thin, the number of special constructs are many. And, of course, all poorly documented. Both SOAP and WSDL have 1.2 versions, which will clear things up a lot, but not used that often yet.
WSDL defines two kinds of messages: document style SOAP and rpc style SOAP. In Document style SOAP, the messages are described in great detail in the WSDL: the message components are all defined in Schema's; the worst things you can (will) encounter are any
schema elements which require additional manual processing.
RPC Literal
behaves very much the same way as document style soap, but has one extra wrapper inside the Body of the message.
Encoded SOAP-RPC
, however, is a very different ball-game. It is simple to use on strongly typed languages, to exchange data when you create both the client software and the server software. You can simply autogenerate the data encoding. Clients written by third parties have to find the documentation on how to use the encoded RPC call in some other way... in text, if they are lucky; the WSDL file does not contain the prototype of the procedures, but that doesn't mean that they are free-format.
Encoded RPC messsages are shaped to the procedures which are being called on the server. The body of the sent message contains the ordered list of parameters to be passed as 'in' and 'in/out' values to the remote procedure. The body of the returned message lists the result value of the procedure, followed by the ordered 'out' and 'in/out' parameters.
Naming types and elements
XML uses namespaces: URIs which are used as constants, grouping a set of type and element definitions. By using name-spaces, you can avoid name clashes, which have frustrate many projects in history, when they grew over a certain size... at a certain size, it becomes too hard to think of good distriguishable names. In such case, you must be happy when you can place those names in a context, and use the same naming in seperate contexts without confusion.
That being said: XML supports both namespace- and non-namespace elements and schema's; and of cause many mixed cases. It is by far preferred to use namespace schemas only. For a schema xsd file, look for the targetNamespace
attribute of the schema
element: if present, it uses namespaces.
In XML data, it is seen as a hassle to write the full length of the URI each time that a namespace is addressed. For this reason, prefixes are used as abbreviations. In programs, you can simply assign short variable names to long URIs, so we do not need that trick.
Within your program, you use
$MYSN = 'long URI of namespace';
... $type => "{$MYNS}typename" ...
or nicer
use XML::Compile::Util qw/pack_type/;
use constant MYNS => 'some uri';
... $type => pack_type(MYNS, 'typename') ...
The XML::Compile::Util module provides a helpfull methods and constants, as does the XML::Compile::SOAP::Util.
Client, Proxy and Server implementations
To learn how to create clients in SOAP, read the DETAILS section in XML::Compile::SOAP::Client. The client implementation is platform independent.
A proxy is a complex kind of server, which in implemented by <XML::Compile::SOAP::Server>, which is available from the XML-Compile-SOAP-Daemon distribution. The server is based on Net::Server, which may have some portability restrictions.
SEE ALSO
This module is part of XML-Compile-SOAP distribution version 2.10, built on February 08, 2010. Website: http://perl.overmeer.net/xml-compile/
All modules in this suite: XML::Compile, XML::Compile::SOAP, XML::Compile::SOAP12, XML::Compile::SOAP::Daemon, XML::Compile::Tester, XML::Compile::Cache, XML::Compile::Dumper, XML::Compile::RPC, and XML::Rewrite, XML::ExistDB, XML::LibXML::Simple.
Please post questions or ideas to the mailinglist at http://lists.scsys.co.uk/cgi-bin/mailman/listinfo/xml-compile For life contact with other developers, visit the #xml-compile
channel on irc.perl.org
.
LICENSE
Copyrights 2007-2010 by Mark Overmeer. For other contributors see ChangeLog.
This program is free software; you can redistribute it and/or modify it under the same terms as Perl itself. See http://www.perl.com/perl/misc/Artistic.html