source:
http://www.ietf.org/internet-drafts/draft-box-http-soap-01.txt
INTERNET-DRAFT D. Box
DevelopMentor
G. Kakivaya
A. Layman
S. Thatte
Microsoft
Corporation
D. Winer
Userland Software
Document: November 1999
Category: Informational
SOAP: Simple Object Access Protocol
Status of this Memo
This document is an Internet-Draft and is in full conformance with
all provisions of Section 10 of RFC2026 [13].
Internet-Drafts are working documents of the Internet Engineering
Task Force (IETF), its areas, and its working groups. Note that
other groups may also distribute working documents as Internet-
Drafts. Internet-Drafts are draft documents valid for a maximum of
six months and may be updated, replaced, or obsoleted by other
documents at any time. It is inappropriate to use Internet- Drafts
as reference material or to cite them other than as "work in
progress."
The list of current Internet-Drafts can be accessed at
http://www.ietf.org/ietf/1id-abstracts.txt
The list of Internet-Draft Shadow Directories can be accessed at
http://www.ietf.org/shadow.html.
1. Abstract
SOAP defines an RPC mechanism using XML for client-server
interaction across a network by using the following mechanisms:
* HTTP as the base transport
* XML documents for encoding of invocation requests and responses
2. Conventions used in this document
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in
this document are to be interpreted as described in RFC-2119 [11].
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The namespace prefix "SOAP" is used in this document to represent
whatever prefix actually appears in the XML instance and is
associated with the SOAP namespace URI "urn:schemas-xmlsoap-
org:soap.v1". The prefix "xsd" represents whatever prefix is
associated with the XML Schemas Specification URI [12].
Namespace URIs such of the general form "some-URI" represent some
application-dependent or context-dependent URI.
3. Introduction
SOAP defines an "XML-RPC" protocol for client-server interaction
across a network by using the following mechanisms:
* HTTP as the base transport
* XML documents for encoding of invocation requests and
responses
SOAP is both low-entry and high-function, capable of use for simple
stateless remote procedure calls as well as rich object systems.
SOAP works with today's deployed World Wide Web and provides
extensibility mechanisms for future enhancements. For example, SOAP
supports submitting invocations using both POST and M-POST.
3.1. Goals
* Provide a standard object invocation protocol built on
Internet standards, using HTTP as the transport and XML for data
encoding.
* Create an extensible protocol and payload format that can
evolve.
3.2. Non-Goals
Define all aspects of a distributed object system, including the
following:
* Distributed garbage collection
* Bi-directional HTTP communications
* Boxcarring or pipelining of messages
* Objects-by-reference (which requires distributed garbage
collection and bi-directional HTTP)
* Activation (which requires objects-by-reference)
3.3. Examples of SOAP Calls
The call is to a StockQuote server, and the method is
GetLastTradePrice. The method takes one string parameter, ticker,
and returns a float.
It uses the SOAP namespace to disambiguate SOAP keywords in the
payload and a method namespace to disambiguate method keywords in
the payload.
The root Envelope element tag name is used to disambiguate SOAP XML
encodings.
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3.3.1. Call
Example #1:
Following is an example of the SOAP encoding required to make this
method call. This example uses the familiar HTTP verb POST. SOAP
also supports the use of the HTTP verb M-POST for extensibility. See
section 6.1 for more information on M-POST.
POST /StockQuote HTTP/1.1
Host: www.stockquoteserver.com
Content-Type: text/xml
Content-Length: nnnn
SOAPMethodName: Some-Namespace-URI#GetLastTradePrice
DIS
3.3.2. Response
Example #2:
Following is the return message containing the HTTP headers and XML
body:
HTTP/1.1 200 OK
Content-Type: text/xml
Content-Length: nnnn
34.5
4. Relation to HTTP
In SOAP, the mechanism used for all communication is HTTP [1]. A
central design goal of SOAP is that SOAP be usable strictly on top
of today's deployed World Wide Web infrastructure. That means SOAP
has to live with and work in the face of various levels of HTTP
implementation, the active use of firewalls and proxies, and so on.
Some aspects of SOAP, such as the permitted use of HTTP methods
beyond those of classic HTTP, are designed to anticipate, and thus
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make use of, some evolution and improvement in this base, but
nothing in SOAP can require such fundamental changes in order for
SOAP to function.
SOAP uses the Content-Type of "text/xml". This is used to specify
the body of the HTTP request containing a XML encoded method call.
To disambiguate the headers it adds to HTTP, SOAP permits use of the
HTTP Extension Framework specification [2].
Unless otherwise indicated in this document, existing practices with
respect to the handling of HTTP requests and responses are to be
adhered to. Specifically, this includes the following:
* Redirection
* Caching
* Connection management
* Support for access authentication and security
5. Relation to XML
XML is used to encode the call and response bodies. See [3] for more
information on XML.
All protocol tags SHOULD be scoped to the SOAP namespace. The sender
SHOULD include namespaces in SOAP elements and attributes. The
receiver MUST correctly process SOAP payloads that have namespaces;
the receiver MUST return an "Invalid Request" fault for requests
that have incorrect namespaces. The receiver MAY also process SOAP
payloads without namespaces as though they had the correct
namespaces.
The SOAP namespace has the proposed value "urn:schemas-xmlsoap-
org:soap.v1". See [6] for more information on XML namespaces.
No XML document forming the HTTP request of a SOAP invocation may
require the use of an XML DTD.
SOAP uses the ID attribute "id" to specify the unique identifier of
an encoded element. SOAP uses the attribute "href" to specify a
reference to that value, in a manner conforming to the XML Linking
Language specification working draft [9].
It is worth noting that the rules governing XML payload format in
SOAP are entirely independent of the fact that the payload is
carried over an HTTP transport.
6. Method Invocation
A method invocation is performed by creating the HTTP request header
and body and processing the returned response header and body. The
request and response headers consist of standard and extended HTTP
headers.
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The following sections will cover the use of standard HTTP headers
and the definition of extended HTTP headers.
6.1. HTTP Verb Rules
SOAP allows two verb options within the Call HTTP header: POST or M-
POST.
The verb M-POST is an extension verb based on in the HTTP Extension
Framework specification [2]. A SOAP invocation MUST first try the
invocation by using POST.
If the POST invocation fails, it SHOULD retry using the HTTP method
M-POST. The details of this mechanism are provided below. The
purpose of supporting this extended invocation mechanism in SOAP is
to provide a mechanism to unambiguously add headers to the HTTP
protocol.
6.2. Using POST vs. M-POST
Since a design goal of the use of M-POST is to provide Internet
firewalls and proxies greater administrative flexibility, careful
attention must be paid as to when a SOAP client uses the POST method
vs. the M-POST method. The rules are as follows:
When carrying out an invocation, a SOAP client MUST first try the
invocation using the POST invocation style.
If that POST invocation fails with an HTTP status of "405 Method Not
Allowed" the client SHOULD retry the request using the M-POST
invocation style. If that M-POST invocation fails with an HTTP
status of "501 Not Implemented" or "510 Not Extended", the client
SHOULD fail the request. If any other HTTP error is returned, it
SHOULD be processed according to the HTTP specification.
Given this algorithm, firewalls can effectively force the use of M-
POST for SOAP invocations by prohibiting POST invocations of
Content-Type "text/xml" containing the HTTP header SOAPMethodName.
6.3. Method Invocation HTTP Headers
The payload and Content-Type of a method call are identical to a
method response except in the following circumstances:
* The method call SHOULD contain additional HTTP header fields
in the request:
a) If using the M-POST verb, a mandatory extension declaration
MUST be present that refers to the namespace "urn:schemas-
xmlsoap-org:soap.v1". For the purposes of this section, suppose
that said declaration chooses to map the namespace to the
header-prefix "01". If the POST verb is used, the namespace
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header-prefix is not used. For example, the SOAPMethodName
header introduced by SOAP would have an M-POST value of "01-
SOAPMethodName" and a POST value of "SOAPMethodName".
b) The request SHOULD include a header "SOAPMethodName" whose
value indicates the method to be invoked on the target. The
value consists of a URI followed by a "#", followed by a method
name (which MUST not include the "#" character). The URI used
for the interface MUST match the implied or specified namespace
qualification of the method name element in the SOAP:Body part
of the payload. For example:
SOAPMethodName: http://electrocommerce.org/abc#MyMethod
* The server MUST return an "Invalid Request" SOAP:Fault if the
required HTTP headers are missing or does not match the payload
exactly. Match means the URI and method name in the HTTP header
exactly match the namespace URI AND LocalPart of the first element
in the SOAP:Body.
6.4. Method Invocation Body
A SOAP method invocation consists of a method call and optionally a
method response. The method call and method response are HTTP
request and response respectively whose content is an XML document
that consists of the root, (optional) header, and (mandatory) body
elements. This XML document is referred to as SOAP payload in the
rest of this specification.
The SOAP payload is defined as follows:
* The SOAP root element is the top element in the XML tree.
* The SOAP payload headers contain additional information that
needs to travel with the call.
* The method request is represented as an XML element with
additional elements for parameters. It is the first child of the
SOAP:Body element.
* The response is the return value or error/exception that is
passed back to the client.
The encoding rules are as follows:
1) Root element
a) The element tag is "SOAP:Envelope".
b) SOAP defines a global attribute "SOAP:encodingStyle" indicating
any serialization rules used in lieu of those described by the
SOAP spec. This attribute MAY appear on any element, and is
scoped to that element and all child elements not themselves
containing such an attribute. Omission of this attribute
indicates that section 8 has been followed (unless overridden
by a parent element). The URI "urn:schemas-xmlsoap-org:soap.v1"
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is defined and all URIs beginning with this one indicate
conformance with section 8 (though with potentially tighter
rules).
c) The root element MAY contain namespace declarations.
d) The root element MAY contain additional attributes, provided
these are namespace-qualified. The root element may contain
additional sub elements provided these are namespace qualified
and follow the body.
2) SOAP payload headers
a) The element tag is "SOAP:Header". If present, this element MUST
be the first element under the root.
b) It contains a list of header entries. Each MUST be namespace-
qualified.
3) Call
a) The element tag is "SOAP:Body".
b) The Body element contains a first sub element whose name is the
method name. This method request element in turn contains elements
for each [in] and [in/out] parameter. The element names are the
parameter names. See section 8 for details.
or
4) Response
a) The element tag is "SOAP:Body".
b) The Body element contains a first sub element that in turn
contains child elements for each [in/out] and [out] parameter. The
element names are the parameter names. See section 8 for details.
or
5) Fault
a) The element tag is "SOAP:Body".
b) The Body element contains a first sub element that is the
SOAP:Fault element, indicating information about the fault.
The version of SOAP used is indicated by the SOAP namespace URI. A
server MUST use the version passed in the envelope of the call for
encoding the response, or it MUST fail the request. In the case
where the server accepts a version or level less than its maximum,
it MUST respond to the client by using the same version and level.
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If a server receives a version it cannot handle, it must return a
"Version Mismatch" SOAP:fault.
Processing requests in the face of missing parameters is application
defined.
See section 7 for information on how to encode parameter values.
6.5. SOAP Payload Headers
In addition to the elements that specify direct, explicit
information about the call or response, SOAP provides a way to pass
extended, implicit information with the call through the use of the
"header" element. It is encoded as a child of the SOAP:Envelope XML
element. It contains a collection of distinctly named entries.
An example of the use of the header element is the passing of an
implicit transaction ID along with a call. Since the transaction ID
is not part of the signature and is typically held in an
infrastructure component rather than application code, there is no
direct way to pass the necessary information with the call. By
adding an entry to the headers and giving it a fixed name, the
transaction manager on the receiving side can extract the
transaction ID and use it without affecting the coding of remote
procedure calls.
Each header entry is encoded as an embedded element. The encoding
rules for a header are as follows:
1. The element's name identifies the header. Header elements
always are namespace-qualified.
2. Unless indicated to the contrary by the value of
"SOAP:encodingStyle" attribute, header values are encoded according
to the rules of section 8.
3. The element MAY contain an attribute "SOAP:mustUnderstand"
specifying required understanding of the header by the destination.
An example is a header with an identifier of "TransactionID", a
"mustUnderstand" value of true, and a value of 5. This would be
encoded as follows:
5
6.5.1. The "SOAP:mustUnderstand" Attribute
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Header entries MAY have a global attribute "SOAP:mustUnderstand".
This may have one of two values, either "1" or "0". The absence of
such a "SOAP:mustUnderstand" attribute is semantically equivalent to
its presence with the value "0".
If a header element is tagged with a "SOAP:mustUnderstand" attribute
whose value is "1", the party processing the Request URI MUST
understand the semantics (as conveyed by its element tag, contextual
setting, and so on) and process correctly to those semantics.
If the SOAP implementation doesn't understand the element, it MUST
return an error as specified in section 7.1, "Results from a Method
Call."
The SOAP:mustUnderstand attribute allows for robust semantic
extensibility and change. Headers tagged with
SOAP:mustUnderstand="1" MUST be presumed to somehow modify the
semantics of their parent or peer elements. Tagging the headers in
this manner assures that this change in semantics will not be
silently (and, presumably, erroneously) ignored by those who may not
fully understand it.
If the "SOAP:mustUnderstand" attribute is missing or has a value of
"0", that element can safely be ignored.
For example: If the client passed along a transaction ID header, as
in the above example, with a "SOAP:mustUnderstand" of "1", then the
server SHOULD fail if it cannot process the transaction ID and
comply with the transactional semantics.
6.6. Making a Method Call
To make a method call, the following information is needed:
* The URI of the target object
* A method name
* An optional method signature
* The parameters to the method
* Optional header data
The target URI of the HTTP request indicates the resource that the
invocation is being made against; in this specification, that
resource is called the "server address," to distinguish it from
other uses of URIs. Other than it be a valid URI, SOAP places no
restriction on the form of an address. See [8] for more information
on URIs.
The body of a SOAP method call MUST be of Content-Type 'text/xml'.
The SOAP protocol places no absolute restriction on the syntax or
case-sensitivity of interface names, method names, or parameter
names. Of course, individual SOAP servers will respond to only the
names they support; the selection of these is at their own sole
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discretion. The one restriction is that the server MUST preserve the
case of names.
6.6.1. Representation of Method Parameters
Method parameters are encoded as child elements of the call or
response, encoded using the following rules:
1) The name of the parameter in the method signature is used as
the name of the corresponding element.
2) Parameter values are expressed using the rules in section 8 of
this document.
6.6.2. Sample Encoding of Call Requests
Example #3:
This sample is the same call as in section 3.3.1 but uses optional
headers. It uses SOAP namespace to disambiguate SOAP keywords in the
payload.
5
DEF
Example #4:
The following request sends a struct:
DEF
DEF Corp
34.1
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7. Results of Method Calls
At the receiving site, a call request can have one of the following
four outcomes:
a) The HTTP infrastructure on the receiving site was able to
receive and process the request.
b) The HTTP infrastructure on the receiving site could not receive
and process the request.
c) The SOAP infrastructure on the receiving site was able to
decode the input parameters, dispatch to an appropriate server
indicated by the server address, and invoke an application-level
function corresponding semantically to the method indicated in the
method call.
d) The SOAP infrastructure on the receiving site could not decode
the input parameters, dispatch to an appropriate server indicated by
the server address, and invoke an application-level function
corresponding semantically to the interface or method indicated in
the method call.
In the first case, the HTTP infrastructure passes the headers and
body to the SOAP infrastructure.
In the second case, the result is an HTTP response containing an
HTTP error in the status field and no XML body.
In the third case, the result of the method call consists of a
response or fault.
In the fourth case, the result of the method is a fault indicating a
fault that prevented the dispatching infrastructure on the receiving
side from successful completion.
In the third and fourth cases, additional payload headers MAY for
extensibility again be present in the results of the call.
7.1. Results from a Method Call
The results of the call are to be provided in the form of a call
response. The HTTP response MUST be of Content-Type "text/xml".
Because a result indicates success and a fault indicates failure, it
is an error for the method response to contain both a result and a
fault.
7.2. SOAP:Fault and HTTP Status Codes
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If the HTTP infrastructure successfully processes the method
request, passes it to the SOAP infrastructure, and an error occurs,
a fault indication is returned to the caller instead of a normal
response. In this section, a SOAP:Fault element is defined. This
element MUST be used to return fault indications.
The standard SOAP:Fault element consists of four sub elements:
* "faultcode", which MUST contain a qualified name value, as
defined in Namespaces in XML [6], section 3 "Qname". If unqualified,
the value is taken from the space of SOAP status codes, described
below. If qualified, the prefix MUST match a declared namespace
prefix. The faultcode is intended for use by software.
* "faultstring", which MUST contain a string value. The
faultstring is intended for use by human users and must not be acted
upon algorithmically by software. faultstring is similar to the
'Reason-Phrase' that may be present in HTTP responses. (See [1],
section 6.1.)
* "runcode", which MUST contain an enumerated value. The runcode
is intended to indicate whether or not the request was dispatched to
the application. There are three runcodes currently defined:
"Maybe", "No", "Yes".
* "detail", which if present MUST contain a value per section 8
with application-specific semantics.
Other sub elements members beyond the three described above MAY be
present, provided they are namespace-qualified.
If the fault specifies a server fault, as opposed to an HTTP fault,
the HTTP status code MUST be "200" and the HTTP status message MUST
be "OK". If it specifies an HTTP fault, the HTTP status code as
defined in the HTTP specification [1] SHOULD be used.
If a method call fails to be processed because of a non-understood
extension header element contained therein, the method invocation
MUST return a fault. The fault MUST contain a 'faultcode' of "Must
Understand".
If a method response fails to be processed for similar reasons, an
appropriate exceptional condition should be indicated to the
application layer in an implementation-defined manner.
7.3. SOAP Status Codes
SOAP defines its own space of status codes. This space is used only
by the SOAP infrastructure and is not expected to be used on HTTP
failure. The reason this space is defined is to aid the conversion
of existing protocols onto SOAP.
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This status code space MUST be used for faultcodes contained in
faults and in the method definitions defined in this specification
that return status code values. Further, use of this space is
recommended (but not required) in the specification of methods
defined outside of the present specification.
The SOAP status code space is identified by the URI, "urn:schemas-
xmlsoap-com:soap.v1/faultcode" and contains numeric values drawn
from the following ranges:
This specification at present defines the following status codes
beyond those specified in [1]:
Name Value Meaning
==== ===== =======
Version Mismatch 100 The call was using an
unsupported SOAP
version.
Must Understand 200 An XML element was
received that contained
an element tagged with
mustUnderstand="1" that
was not understood by
the receiver.
Invalid Request 300 The receiving
application did not
process the request
because it was ill
formed or not supported
by the application.
Application Faulted 400 The receiving
application faulted
processing the request.
The 'detail' element
contains the
application specific
fault.
7.4. Sample Encoding of Response
Example #5:
The response from the example in section 3.3.2 would be:
HTTP/1.1 200 OK
Content-Type: text/xml
Content-Length: nnnn
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34.5
Example #6:
The following response is similar to the one above, but uses
optional headers.
HTTP/1.1 200 OK
Content-Type: text/xml
Content-Length: nnnn
5
34.5
Example #7:
The following response returns a struct:
HTTP/1.1 200 OK
Content-Type: text/xml
Content-Length: nnnn
34.5
10000
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Example #8:
If there was an error in the HTTP infrastructure, the response could
be as follows:
HTTP/1.1 401 Unauthorized
Example #9:
If there was an error in the SOAP infrastructure processing the
request on the server, the response could be as follows:
HTTP/1.1 200 OK
Content-Type: text/xml
Content-Length: nnnn
200
SOAP Must Understand Error
1
Example #10:
If the application passed back its own fault element, the response
would be as follows:
HTTP/1.1 200 OK
Content-Type: text/xml
Content-Length: nnnn
400
SOAP Must Understand Error
1
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My application didn't work
1001
8. Types
SOAP uses a simple, traditional type system. A type either is a
simple (scalar) type or is a compound type constructed as a
composite of several parts, each with a type.
Because all types are contained or referenced within a call or
response element, the encoding samples in this section assume all
namespace declarations are at a higher element level.
8.1. Rules for Encoding Types in XML
XML allows very flexible encoding of data to represent a method
call. SOAP defines a narrower set of rules for encoding. This
section defines the encoding rules at a high level, and the next
section describes the encoding rules for specific types when they
require more detail.
To describe encoding, the following terminology is used:
1. A "type" includes integer, string, point, or street address. A
type in SOAP corresponds to a scalar or structured type in a
programming language or database. All values are of specific types.
2. A "compound type" is one that has distinct, named parts and
whose encoding should reflect those named parts. A "simple type" is
one without named parts. A structured type in a programming language
is a compound type, and so is an array.
3. The name of a parameter or of a named part of a compound type
is called an "accessor."
4. If only one accessor can reference it, a value is considered
"single-reference" for a given schema. If referenced by more than
one, actually or potentially in a given schema, it is "multi-
reference." Therefore, it is possible for a certain type to be
considered "single-reference" in one schema and "multi-reference" in
another schema.
5. Syntactically, an element MAY be "independent" or "embedded."
An independent element is contained immediately by its scoping
element. An embedded element is contained within a non-scoping
element. Examples of scoping element in this specification are
"SOAP:Header" and "SOAP:Body".
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The rules are as follows:
1. Elements MAY be used to reflect either accessors or instances
of types. Embedded elements always reflect accessors. Independent
elements always reflect instances of types. When reflecting an
accessor, the name of the element gives the name of the accessor.
When reflecting an instance of a type, the name of the element
typically gives the name of the type.
2. A call or response/fault is always encoded as an independent
element.
3. Accessors are always encoded as embedded elements.
4. A value (simple or compound) is encoded as element content,
either of an element reflecting an accessor to the value or of an
element reflecting an instance of that type.
5. A simple value is encoded as character data, that is, without
any sub elements.
6. Strings and byte arrays are multi-reference simple types, but
special rules allow them to be represented efficiently for common
cases. An accessor to a string or byte-array value MAY have an
attribute named "id" and of type "ID" per the XML Specification [3].
If so, all other accessors to the same value are encoded as empty
elements having an attribute named "href" and of type "URI" per the
XML Linking Language Specifications [9], with the href containing a
URI fragment identifier referencing the single element containing
the value.
7. It is permissible to encode several references to a simple
value as though these were references to several single-reference
values, but only when from context it is known that the meaning of
the XML instance is unaltered.
8. A compound value is encoded as a sequence of elements, each
named according to the accessor it reflects. (See also section
8.4.1.)
9. A multi-reference simple or compound value is encoded as an
independent element containing an attribute named "id" and of type
"ID" per the XML Specification [3]. Each accessor to this value is
an empty element having an attribute named "href" and of type "URI"
per the XML Linking Language Specification [9], with the href
containing a URI fragment identifier referencing the corresponding
independent element.
10. Arrays are compound types. Arrays can be of one or more
dimensions (rank) whose elements are normally laid contiguously in
memory. Arrays can be single-reference or multi-reference values.
Single-reference embedded arrays are encoded using accessor
elements. A multi-reference array is always encoded as an
independent element whose tag name is the string "ArrayOf" prepended
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to the element type of the array. The independent element or the
accessor MUST contain a "xsd:type" attribute that specifies the type
and dimensions of the array and is encoded as the type of the array
element, followed by "[", followed by comma-separated lengths of
each dimension, followed by "]". The "xsd:type" attribute is
described in the "XML Schema Part 2: Datatypes" Specification (see
12]. Note that the array element itself can be an array. An array
type is encoded as its element type, followed by "[", followed by
rank encoded as a sequence of commas(one for each dimension),
followed by "]". It MAY also contain an "offset" attribute to
indicate the starting position of a partially represented array.
Each element of an array is encoded using the accessor named after
the type of array element. The elements are represented as a list
with the dimension on the right side varying rapidly. The accessor
MAY contain the "position" attribute that conveys the position of
the item in the enclosing array. Both "offset" and "position"
attributes are encoded as "[", followed by a comma-separated
position in each dimension, followed by "]", with offsets and
positions based at 0.
11. Any accessor element that contains its value directly MAY
optionally have an attribute named "xsd:type" whose value indicates
the type of the element's contained value as described in the "XML
Schema Part 2: Datatypes" Specification [12]. However, its presence
is mandatory on elements whose tag name combined with implicit or
explicit namespace does not unambiguously identify the type of the
element.
12. A NULL value is indicated by an attribute named "xsd:null" with
value of '1'.
13. In many cases, it is necessary to package multiple related
elements as a single element, for instance in cases where the
elements are linked together via hrefs. SOAP defines another
attribute "SOAP:Package" whose value can be "0" or "1". If "1" the
element acts as a scoping element for contained sub elements.
8.2. Simple Types
For simple types, SOAP adopts the types found in the section "Built-
in datatypes" of the "XML Schema Part 2: Datatypes" Specification
[12], along with the corresponding recommended representation
thereof. Examples include:
integer: 58502
real: 314159265358979E+1
negative-integer: -32768
Strings and arrays of bytes are encoded as multi-reference simple
types.
8.2.1. String
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SOAP: Simple Object Access Protocol November, 1999
A string is a multi-reference simple type. According to the rules of
multi-reference simple types, the containing element of the string
value MAY have an ID attribute; additional accessor elements MAY
then have matching href attributes.
For example, two accessors to the same string could appear, as
follows:
Hello
However, if the fact that both accessors reference the same instance
of the string is immaterial, they may be encoded as though single-
reference, as follows:
Hello
Hello
8.2.2. Enums
An enum is a single reference type whose value is encoded as one of
the possible enumeration strings. In the following example EyeColor
is an enum with the possible values of "Green", "Blue", and "Brown":
Henry Ford
32
Brown
8.2.3. Array of Bytes
An array of bytes is encoded as a multi-reference simple type. The
recommended representation of an opaque array of bytes is the
'bin.base64' encoding defined in XML DCD [5], which simply
references the MIME standard. However, the line length restrictions
that normally apply to Base64 data in MIME do not apply in SOAP.
bin.base64: aG93IG5vdyBicm93biBjb3cNCg==
8.3. Polymorphic Accessor
Many languages allow accessors that can polymorphically access
values of several types, each type being available at run-time. When
the value is single-reference, the type of this kind of accessor is
often called "Variant". A Polymorphic accessor MUST contain a
"xsd:type" attribute that describes the type of the actual value.
For example, a Polymorphic parameter named "cost" with a type of
float would be encoded as follows:
29.95
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SOAP: Simple Object Access Protocol November, 1999
as contrasted with a cost parameter whose type is invariant, as
follows:
29.95
8.4. Compound Types
Beyond the simple types, SOAP defines support for the following
constructed types:
* Records/structs
* arrays
Where appropriate and possible, the representation in SOAP of a
value of a given type mirrors that used by practitioners of XML-Data
and the common practice of the XML community at large.
8.4.1. Compound Values and References to Values
A compound value contains an ordered sequence of structural members.
When the members have distinct names, as in an instance of a C or
C++ "struct", this is called a "struct," and when the members do not
have distinct names but instead are known by their ordinal position,
this is called an "array.
The members of a compound value are encoded as accessor elements.
For a struct, the accessor element name is the member name. For an
array, the accessor element name is the element type name and the
sequence of the accessor elements follows the ordinal sequence of
the members.
The following is an example of a struct of type Book:
Henry Ford
Prefatory text
This is a book.
Below is an example of a type with both simple and compound members.
It shows two levels of referencing.
Note that the "href" attribute of the Author accessor element is a
reference to the value whose "id" attribute matches; a similar
construction appears for the Address.
My Life and Work
Henry Ford
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SOAP: Simple Object Access Protocol November, 1999
henryford@hotmail.com
www.henryford.com
The form above is appropriate when the Person value and the Address
value are multi-reference. If these were instead both single-
reference, they SHOULD be embedded, as follows:
My Life and Work
Henry Ford
henryford@hotmail.com
www.henryford.com
If instead there existed a restriction that no two persons can have
the same address in a given schema and that an address can be either
a Street-address or an Electronic-address, a Book with two authors
would be encoded in such a schema as follows:
My Life and Work
Henry Ford
henryford@hotmail.com
www.henryford.com
Thomas Cook
Martin Luther King Rd
Raleigh
North Carolina
8.4.1.1. Generic Records
There are cases where a struct is represented with its members named
and values typed at run time. Even in these cases, the existing
rules apply. Each member is encoded as an element with matching
name, and each value is either contained or referenced. Contained
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SOAP: Simple Object Access Protocol November, 1999
values MUST have a "xsd:type" attribute giving the type of the
value.
8.4.2. Arrays
The representation of the value of an array is an ordered sequence
of elements constituting items of the array. The default tag name
for each element is the element type.
As with compound types generally, if the type of an item in the
array is a single-reference type, each item contains its value.
Otherwise, the item references its value via an href attribute.
The following example is an array containing integer array members.
The length attribute is optional.
3
4
The following example is an array of Variants containing an integer
and a string.
23
some string
The following is an example of a two-dimensional array of strings.
r1c1
r1c2
r1c3
r2c1
r2c2
r2c3
The following is an example of an array of two arrays, each of which
is an array of strings.
r1c1
r1c2
r1c3
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SOAP: Simple Object Access Protocol November, 1999
r2c1
r2c2
Finally, the following is an example of an array of phone numbers
embedded in a struct of type Person and accessed through the
accessor "phone-numbers":
John Hancock
111-2222
999-0000
A multi-reference array is always encoded as an independent element
whose tag name is the string "ArrayOf" prepended to the element type
of the array. For example an array of order structs encoded as an
independent element:
Apple
1.56
Peach
1.48
A single-reference array is encoded as an embedded element whose tag
name is the accessor name.
Henry Ford
5th Ave
New York
NY
10010
Apple
1.56
Peach
1.48
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SOAP: Simple Object Access Protocol November, 1999
8.4.2.1. Partially transmitted arrays
SOAP provides support for partially transmitted arrays, known as
"varying" arrays, in some contexts [7]. A partially transmitted
array indicates in an "offset" attribute the zero-origin index of
the first element transmitted; if omitted, the offset is taken as
zero.
The following is an example of an array of size five that transmits
only the third and fourth element:
The third element
The fourth element
8.4.2.2. Sparse Arrays
SOAP provides support for sparse arrays in some contexts. Each
element contains a "position" attribute that indicates its position
within the array. The following is an example of array of arrays of
strings:
The third element"
The eighth element
Assuming that the only reference to array-1 occurs in the enclosing
array, this example could also have been encoded as follows:
The third element"
The eighth element
8.5. Default Values
An omitted accessor element implies either a default value or that
no value is known. The specifics depend on the accessor, method, and
its context. Typically, an omitted accessor implies a Null value for
Variant and for polymorphic accessors (with the exact meaning of
Null accessor-dependent). Typically, an omitted Boolean accessor
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SOAP: Simple Object Access Protocol November, 1999
implies either a False value or that no value is known, and an
omitted numeric accessor implies either that the value is zero or
that no value is known.
9. Formal Syntax
This specification uses the augmented Backus-Naur Form (BNF) as
described in RFC-2234 [10].
10. Security Considerations
Not described in this document are methods for integrity and privacy
protection. Such issues will be addressed more fully in a future
version(s) of this document.
11. References
[1] RFC2068: Hypertext Transfer Protocol,
http://info.internet.isi.edu/in-notes/rfc/files/rfc2068.txt. Also:
http://www.w3.org/Protocols/History.html.
[2] HTTP Extension Framework,
http://www.w3.org/Protocols/HTTP/ietf-http-ext.
[3] The XML Specification, http://www.w3.org/TR/WD-xml-lang.
[4] XML-Data Specification, http://www.w3.org/TR/1998/NOTE-XML-
data.
[5] Document Content Description for XML,
http://www.w3.ort/TR/NOTE-dcd.
[6] Namespaces in XML, http://www.w3.org/TR/REC-xml-names.
[7] Transfer Syntax NDR, in "DCE 1.1: Remote Procedure Call,"
http://www.rdg.opengroup.org/onlinepubs/9629399/toc.htm.
[8] RFC 2396: Uniform Resource Identifiers (URI): Generic Syntax
and Semantics, http://www.ietf.org/rfc/rfc2396.txt.
[9] XML Linking Language, http://www.w3.org/1999/07/WD-xlink-
19990726.
[10] RFC-2234: Augmented BNF for Syntax Specifications: ABNF
[11] Bradner, S., "Key words for use in RFCs to Indicate Requirement
Levels", BCP 14, RFC 2119, March 1997
[12] XML Schema Part 2: Datatypes, http://www.w3.org/TR/1999/WD-
xmlschema-2-19991105/
[13] RFC2026: The Internet Standards Process -- Revision 3,
http://info.internet.isi.edu/in-notes/rfc/files/rfc2026.txt.
12. Author's Addresses
Don Box
DevelopMentor
21535 Hawthorne Blvd., Fourth Floor
Torrance, CA 90503
Email: dbox@develop.com
Gopal Kavivaya
Microsoft
One Microsoft Way
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SOAP: Simple Object Access Protocol November, 1999
Redmond, WA 98052
Email: gopalk@microsoft.com
Andrew Layman
Microsoft
One Microsoft Way
Redmond, WA 98052
Email: andrewl@microsoft.com
Satish Thatte
Microsoft
One Microsoft Way
Redmond, WA 98052
Email: satisht@microsoft.com
Dave Winer
UserLand Software, Inc.
P.O. Box 1218
Burlingame, CA 94011-1218
Email: dave@userland.com
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SOAP: Simple Object Access Protocol November, 1999
Full Copyright Statement
"Copyright (C) The Internet Society (date). All Rights Reserved.
This document and translations of it may be copied and furnished to
others, and derivative works that comment on or otherwise explain it
or assist in its implmentation may be prepared, copied, published
and distributed, in whole or in part, without restriction of any
kind, provided that the above copyright notice and this paragraph
are included on all such copies and derivative works. However, this
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the copyright notice or references to the Internet Society or other
Internet organizations, except as needed for the purpose of
developing Internet standards in which case the procedures for
copyrights defined in the Internet Standards process must be
followed, or as required to translate it into.
Box, Kakivaya, et al. HTTP -- June, 2000 27