Many enterprise IT folk seem to believe that REST is only suitable for lightweight integration or for relatively simple data manipulation (CRUD). On the contrary, by applying well-understood design patterns, REST can provide capabilities that only traditional enterprise integration tools have been able to provide - high performance, asynchronous messaging, reliability, etc.
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Enterprise REST
1. Implementing SOA*
in the
Enterprise using a REST**
Approach
Ganesh Prasad
* SOA = Service-Oriented Architecture ** REST = REpresentational State Transfer
2. Intended Audience
This presentation is addressed to the Enterprise Architect responsible
for setting out a target and roadmap for the middle tier of an
enterprise, what is commonly known as the “SOA direction”.
You, the architect, understand:
- Organisational structure, business drivers, strategies, politics
- Product systems, applications, functionality overlaps and gaps
- Interface and integration complexity
- Qualities of service demanded and currently provided
- Scale, volume and performance
- Costs and risks
You are knowledgeable in a variety of disciplines.
Yet you are also intensely pragmatic. You seek solutions to your
problems without preconceptions and other ideological baggage.
This presentation is about a simple, cost-effective and extremely
practical way to achieve your key deliverable, i.e., an implementable
vision of SOA.
3. Recap: Fundamental Principles of SOA
SOA is an architecture for business and technology components
wherein implicit dependencies are eliminated and all legitimate
dependencies between components are stated as explicit contracts.
SOA can deliver greater connectivity, flexibility and reusability, with
the ultimate business benefits being agility, lower time-to-market and
sustainably lower costs.
The fundamental principles behind SOA are:
1. Explicit Boundaries
2. Shared Contract and Schema, not Class
3. Policy-Driven
4. Autonomous
5. Wire Formats, not Programming Language APIs
6. Document-Oriented
7. Loosely-Coupled
8. Standards-Compliant
9. Vendor-Independent
10. Metadata-Driven
- Ten Principles of SOA, Stefan Tilkov (InfoQ)
http://www.infoq.com/articles/tilkov-10-soa-principles
4. Observation: Web Technology Satisfies SOA Principles
Fact: The Web is a simple, flexible, scalable, low-cost platform for application
development. (Proof: The many millions of Internet/Intranet applications
developed since 1994, when the Web officially began.)
Observation: The Web is not restricted to the transfer of visual HTML markup
for consumption by human users with browsers. It can be used to transfer
non-visual data (XML documents) between computer systems as well.
Insight: SOA objectives are achievable very simply using Web technology.
There is no need to define specialised protocols like SOAP or use specialised
adapters, brokers, registries and other new infrastructure.
SOA Principles
1. Explicit Boundaries
2. Shared Contract & Schema
3. Policy-Driven
4. Autonomous
5. Wire Formats, not APIs
6. Document-Oriented
7. Loosely-Coupled
8. Standards-Compliant
9. Vendor-Independent
10. Metadata-Driven
Web Technology measured against SOA principles
1. URLs define endpoints, abstract away implementations
2. Contract: URLs, HTTP verbs and XML document payloads
3. Client and server can negotiate capabilities*
4. Dependencies on interfaces alone, not implementations
5. Only needs a wire format - HTTP protocol + XML payload
6. (XML) document is the HTTP payload
7. Satisfies many dimensions of loose coupling**
8. No dependence on proprietary/non-standard technology
9. No dependence on vendor-specific features
10. Easy to describe, easy to consume based on description
* E.g., “Accept” and “Content-type” headers
** Location-transparent, interface dependency only, proxyable, can
support asynchronous models (polling and callback)
5. Yes, but is REST truly “Enterprise Class”?
This is really a question of confidence. A new concept (even a sudden return
to basics) does not inspire confidence because it challenges established
“truths”.
As enterprise architects, we are familiar with web technology.
Many important product systems and applications have been built as web
apps, and they work quite well.
But...
“HTTP is a synchronous request/response protocol. We have many enterprise
requirements for asynchronous communication. A synchronous constraint would be too
limiting in our context.”
“HTTP is not a reliable protocol. We already have far more reliable communication
infrastructure in our enterprise, e.g., message queues.”
“I'm frankly skeptical. I don't believe everything can be reduced to a URI.”
“I also think that a CRUD interface is too simplistic to cover all possible use cases when
dealing with resources.”
“A lot of very smart people from large organisations that understand enterprise issues
have worked on SOAP, WSDL and all the WS-* standards. Are you telling me these REST
people know something that they don't?”
6. Reframing situations leads to new insights
Old woman or young?
Practically, asynchronous behaviour refers to either
fire-and-forget, polling or callbacks. Can't these be
implemented with HTTP? Think Design Patterns.
Often, when we say “at-most-once delivery”, we
really mean “at-most-once processing”. That's
idempotence, not reliable messaging – a different
problem. Also, transactional integrity is different
from uncertainty over transaction status. What is the
real problem we are trying to solve?
The URI abstraction is analogous to the file
abstraction in Unix. Unix treats everything as a file,
even processes (/proc/43437) and hardware devices
(/dev/mouse). That abstraction more than just
works. It makes the design of Unix elegant.
A CRUD interface isn't necessarily simplistic. It's
polymorphic. Each resource responds differently to
the same request. We know that polymorphism,
more than inheritance, gives OO its power.
The smartness of committees: Everybody but
Copernicus knew the Earth was the centre of the
universe. Everybody but Columbus knew the Earth
was flat. Who were these upstarts anyway?
7. What REST is not
Despite sharing the basic technology, REST is more than just
traditional web application development. There are principles that an
application must adhere to, to be considered RESTian. Many, perhaps
most, web applications that have been built so far consciously or
unconsciously violate REST principles. Indeed, complacency around
REST (“We've been doing this for years”) can prevent exploitation of
its benefits.
REST is not a set of hard-and-fast rules or a set of DOs and DON'Ts. It
is not a methodology. It is considered an architectural style, which
makes it too abstract for some. Nevertheless, it has a discipline that
must be understood and applied before its benefits can be realised.
REST is not a product one can purchase from a vendor. It is not even
an Open Source product. However, RESTian applications can be
implemented using commodity products from any source. The only
software component required is typically a programmable (dynamic)
web server, ideally with XML processing capability.
8. High Level Overview of a RESTful System
URI
URI
URI
URI URI
URI URI
1. The System is modelled as a set of uniquely
identifiable resources and collections thereof, based
on how it needs to appear to external parties.
2. URIs are used
to uniquely
identify resources.
3. URIs are used to
hyperlink resources
together into a
'resource graph'.4. Regardless of the nature of the application domain (Banking,
Insurance, Airlines, etc.), consumers of the system's services do
not use specialised verbs to interact with it. Generally speaking,
four standard verbs corresponding to Create, Retrieve, Update
and Delete are sufficient, although a limited superset is also
possible. If this seems too fine-grained, remember that the
resources on which they act can be defined to be arbitrarily
coarse-grained.
Service
Consumer
Create
Retrieve
Delete
Update
5. The resource graph is only a logical representation of the actual domain model that is
exposed to external parties (service consumers). This representation is mapped back to
domain objects as part of the SOA implementation. This is how loose coupling is achieved.
The actual domain model is never exposed to external parties, only its representation as a
resource graph supporting a few standard operations. That is the RESTful service contract.
Domain
Model
Implementation
9. Semantics of HTTP Verbs in REST
GET means Retrieve Details when applied to a specific resource
http://www.xyz.com/customers/76772374 <= retrieve details of this customer
GET means List when applied to a collection
http://www.xyz.com/customers <= retrieve list of customers
GET can also mean Search (selective retrieval) when appropriate
parameters are passed
http://www.xyz.com/customers/?postcode=2345 <= search for customers in this area
DELETE is applied to a specific resource, not to a collection
http://www.xyz.com/customers/76772374 <= delete this customer
DELETE only means the resource will no longer be accessible
through this URI after this operation. Further attempts to access
this URI will result in a 404 error (resource not found). The actual
domain entity may still exist (say in an archived fashion) and may
be accessible by back-end applications that don't use the REST
interface.
10. Semantics of HTTP Verbs in REST
POST and PUT have more nuanced semantics.
PUT means “Create or Update” and always refers to a particular
resource, not to a collection. If the resource does not already exist, it is
created and the given URI is associated with it from then on, provided
the data payload satisfies the correctness and completeness
requirements for resource creation. If the resource already exists, the
associated data payload determines which attributes of the resource
must be updated.
http://www/xyz.com/customers/76772374 <= change billing address
<billing-address>
... <= payload specifying attribute for update
</billing-address>
POST means Create (Insert) and is normally applied to collections. A URI
is generated by the system, associated with the newly-created resource
and returned as part of the response to this request. POST is also a
catch-all verb and may be used to handle odd cases that don't neatly fit
the semantics of the other verbs.
http://www.xyz.com/customers/ <= create a new customer
<customer-details>
... <= payload with full details of customer
</customer-details>
11. Idempotence and Safety of HTTP Verbs in REST
Non-idempotent (hence
unsafe) operations
Idempotent (but
unsafe) operations
Safe (hence
idempotent)
operations
POST
PUT
DELETE
GET
Venn Diagram showing the inter-relationship between Idempotence* and Safety**, and where the
HTTP verbs used by REST lie within this area.
*An idempotent operation has the same effect when it is performed multiple times as when it is performed exactly once.
**A safe operation has no side-effects. Queries/reads/retrievals are the canonical safe operations.
All safe operations are idempotent, but the reverse is not necessarily true.
12. HTTP Status Codes and their Meanings
REST is not just about 4 verbs to formulate requests. The status codes
of responses convey many nuances of meaning.
1xx – Informational
100 Continue
101 Switching Protocols
2xx – Successful
200 OK
201 Created
202 Accepted
203 Non-authoritative Information
204 No Content
205 Reset Content
206 Partial Content
3xx – Redirection
300 Multiple Choices
301 Moved Permanently
302 Found
303 See Other
304 Not Modified
305 Use Proxy
306 (unused)
307 Temporary Redirect
4xx – Client Error
400 Bad Request
401 Unauthorized
402 Payment Required
403 Forbidden
404 Not Found
405 Operation Not Permitted
406 Not Acceptable
407 Proxy Authentication Required
408 Request Timeout
409 Conflict
410 Gone
411 Length Required
412 Precondition Failed
413 Request Entity Too Large
414 Request-URI Too Long
415 Unsupported Media Type
416 Request Range Not Satisfiable
417 Expectation Failed
5xx – Server Error
500 Internal Server Error
501 Not Implemented
502 Bad Gateway
503 Service Unavailable
504 Gateway Timeout
505 HTTP Version Not Supported
14. What would RESTful Internet Banking look like?
The Customer resource:
http://www.xyz.com/customers/76772374 <= A particular customer, uniquely identified
http://www.xyz.com/customers <= The set of all customers
The Account resource:
http://www.xyz.com/customers/76772374/accounts <= This customer's accounts
http://www.xyz.com/accounts/675653-767973 <= A particular account (may be jointly held)
Account List Query:
GET => http://www.xyz.com/customers/76772374/accounts
may return many records in this form (note the hyperlink):
<account-list>
<account href=”http://www.xyz.com/accounts/675653-767973”
account-number=”675653-767973”
account-balance=”5042.74”/>
...
</account-list>
This data may be processed or displayed, and also used for further queries (below):
Account Statement Query:
GET => http://www.xyz.com/accounts/675653-767973 <= use hyperlink from previous query
15. What would RESTful Internet Banking look like?
Updates:
Change of Address (Idempotent but not Safe):
PUT => http://www.xyz.com/customers/76772374 <= update a particular customer's details
<address street-number=”23/56” street-name=”Rest Mews” suburb=”Epping” post-code=”2121” />
Funds Transfer (Inherently neither Idempotent nor Safe):
GET => http://www.xyz.com/transfers/?new
Returns a confirmation URI (one-time access only):
http://www.xyz.com/transfers/R5YU780A32JK9Y
Perform the transfer using this one-time URI:
POST => http://www.xyz.com/transfers/R5YU780A32JK9Y <= cannot be re-accessed, ensuring idempotence
<transfer-request from-account=”657653-767973” to-account=”876456-676786” amount=”1000.00”/>
Returns 202 Accepted (HTTP Status) the first time if successful, or an error status if not.
Accidentally repeating the transfer request will return a 405 (Operation Not Permitted) response
because the URI, being one-time, is no longer accessible after the first successful POST.
This is REST's simple way of ensuring idempotent operations.
17. Caching and Performance Optimisation in REST
Because GET is safe (and idempotent), it can be cached, improving performance.
Caveats:
1. GET must never be implemented with side-effects:
GET http://www.xyz.com/accounts/675653-767973?action=delete <= This is not RESTful usage
2. Time-sensitive data must support negotiation around expiry:
Send “If-modified-since” HTTP header along with the GET request
If content remains unchanged, server responds simply with “304 Not Modified” header
and does not re-send the data
If content has changed, server responds with “200 OK” response, a “Last-Modified” header
and the new data
Etags are another way to determine if content has changed.
Etags are like a hash or digest of the content that indicates whether content has changed or
not. A caching proxy can send a lightweight HEAD request to the origin server. If the Etag in
the header has not changed, the proxy can safely serve up the response from its own cache
without hitting the origin server with the full request.
Comparison with SOAP: Note that because SOAP-based service operations are arbitrarily named,
there is no automated way to determine whether they are safe and idempotent. Hence it is not
possible for infrastructural components like caching proxies to seamlessly improve performance
without special (read: application-aware) configuration.
18. Enterprise Queueing vs REST – which is more performant?
Enterprise Message Queueing products are highly optimised for performance
and support both vertical and horizontal scalability. At high levels of scalability
though, such infrastructure can be quite expensive.
A standard web server is moderately scalable, but a load-balanced web server
farm is much more scalable, especially for stateless interactions. Since REST is
a stateless architecture, adequate performance for most applications is
achievable with inexpensive commodity hardware.
The justification for enterprise queueing products is therefore much lower with
a REST model.
19. Asynchronous Communications using REST
REST uses HTTP, which is a synchronous request/response protocol.
How can we use RESTful techniques to support asynchronous
interactions? E.g., Long-running processes when service consumer
cannot afford to “block” on the response.
Three standard patterns (independent of REST):
- Fire-and-forget (service consumer does not wait for a response)
- Polling (service consumer periodically polls the status)
- Callback (service provider calls consumer back when done)
20. How REST implements Asynchronous Interactions – 1
Fire-and-Forget (Reliable one-way
messaging)
Service
Consumer
Load
Balancer
Active
Web Server
POST
202 Accepted
<data/>
Active
Web Server
Failed
Web Server
Heartbeat
Heartbeat
Heartbeat
Response
Response
Timeout
...
...
POST
<data/>
202 Accepted
Choose
physical
server based
on LB
algorithm
Merely an
acknowledgement
of the request, not
the response
Web Server Farm
A single web server is less reliable and available than enterprise queueing infrastructure.
But a load-balanced web server farm approaches queueing infrastructure in availability.
Reliable one-way messaging (fire-and-forget) can thus be implemented simply and
21. How REST implements Asynchronous Interactions – 2
Polling
Service
Consumer
Service
Provider URI
Status Query
URI
POST
Status Query URI
GET
404 Not found
GET
404 Not found
GET
200 OK
...
<data>
...
</data>
202 Accepted Merely an
acknowledgement of the
request, not the
response
Repeated
Polling
<data/>
22. How REST implements Asynchronous Interactions – 3
Callback
Service
Consumer
Service
Provider URI
Callback
Subscription
URI
POST
Callback Subscription URI
202 Accepted
Merely an
acknowledgement
of the request, not
the response
POST
Callback URI
202 Accepted
Callback
URI
POST
<data>
...
</data>
Notification
Service
...
<data/>
23. Reliable Messaging/Guaranteed Delivery using REST
In many cases, even if we say we want guaranteed delivery, we are
really concerned about the uncertainty surrounding transaction status.
1. “Guaranteed Delivery” is a chimera when we also want
acknowledgements of the delivery. This reduces to the “Two-Army
Problem” of networking theory which is proven to be unsolvable.
2. “At-Most-Once Delivery” is in fact a requirement for “At-Most-Once
Processing” (i.e., Idempotence).
3. Uncertainty is less of a problem if idempotence can be guaranteed.
If in doubt, retry the request!
24. Enterprise Queueing vs REST – which is more “reliable”?
Service
Consumer
Service
Provider
Request Queue
Response Queue
1. The Service
Consumer places a
request message
on the Request
Queue.
2. The Service
Provider pulls the
request message
off the Request
Queue.
3. The Request Queue confirms to the
Service Consumer that the message has
been delivered.
4. The Service Provider
processes the
message (e.g.,
updates a resource in
a non-idempotent
way).
5. The Service
Provider places
either a Success or
Failure message on
the Response Queue.
6. The Service
Consumer pulls the
status message
(Success/Failure) off
the Response Queue.
7. The Response Queue confirms to the
Service Provider that the message has been
delivered.
The two queues guarantee message delivery and even confirm delivery to the application at the other end. However,
the possibility of a fatal error between steps 2 and 4, or between steps 4 and 5, means that end-to-end guarantees of
the business transaction are not possible.
In the first case (fatal error between steps 2 and 4), the message is not acted upon and the resource is not updated.
In the second (fatal error between steps 4 and 5), the message is acted upon, the resource updated, but no status
message is placed on the Response Queue.
In either case, the Service Consumer fails to receive a response, hence is uncertain whether the transaction was
processed or not. Since the operation is non-idempotent, it cannot be safely retried.
Hence guaranteed message delivery alone is not a solution to the critical requirement of an Exactly
Once business transaction.
Enterprise Message Queueing infrastructure is expensive, but ironically does not address this business requirement.
REST addresses the business requirement through the POST-Exactly-Once pattern which guarantees idempotence and
makes uncertainty a non-issue. It is also inexpensive.
Even with reliable queues, round-trip reliability is impossible to achieve
The Service
Consumer wants to
be certain about
the status of their
service request,
whether success or
failure. Is this
possible using
reliable queueing?
25. How REST implements Idempotent Operations
Service
Consumer
Service
Provider URI
One-Time URI
GET
One-time URI
200 OK
The consumer is asking for a
one-time URI. This is an
idempotent operation and can
safely be done any number of
times, as long as only one of the
returned URIs is POSTed to.
POST
<data>
...
</data>202 Accepted
...
405 Operation Not Permitted
The first time the
POSTed data is
received and
processed, the URI is
marked “used” and
will no longer be
valid.
The URI is no longer
accessible. This indicates
that a previous POST
was successful.
POST
Even if we assume
that the consumer
does not receive the
acknowledgement of
the transaction,
there is no danger of
a duplicate update if
the POST is retried.
Idempotence is
guaranteed by the
one-time URI.
The POST-Once-Exactly (POE) Pattern
Many enterprise requirements for “guaranteed delivery” (where the concern is not timeliness but the impact of
erroneous retries due to uncertainty) can be satisfied by ensuring idempotence. A focus on the real underlying issue
makes REST an attractive and less expensive solution compared to strong queueing infrastructure.
Besides, the point-to-point guaranteed delivery of queueing systems does not provide round-trip guarantees, which
idempotence addresses (next slide).
<data>
...
</data>
The one-time
URI may be
persisted in case
a crash occurs
between the
POST and the
receipt of its
response.
26. REST and the Presentation/Service Divide
Traditionally, this is the way we have viewed Presentation and the Service
Tier:
Presentation
Support
(Web server)
Business Logic
Non-visual interface
Visual interface
But this is the REST model:
Browser
Application
RESTful
Resource
GET (Accept: text/html)
GET (Accept: application/xml)
HTML response
XML response
Browser
Other
Application
The same resource can return various representations of itself, both visual and
non-visual. In effect, a web app can itself provide a service interface.
The resource responds with
a representation of itself
that suits what the service
consumer says it wants
through the “Accept” HTTP
header.
27. How does REST compare in terms of infrastructure
cost and development effort?
SOAP/WS-*:
● Application Server
● SOAP Engine
● ESB/Broker
● Message Queues
● Legacy/Infrastructure Adapters
● Registry/Repository
● Specialised Dev Tools
● Specialised Management Tools
$$$ + development effort
REST:
● Any programmable Web Server,
e.g., Tomcat or Apache/PHP (Full-
fledged JEE App Servers are
overkill)
● Legacy/Infrastructure Adapters
● DNS Server
● Standard Web + XML Dev Tools
● Standard Web Management Tools
Most infrastructure already exists.
Much less development effort
28. Infrastructural components required for REST
Programmable Web Server/Servlet Engine
CICS
Transaction
Gateway
Web container
Hibernate/
JDBC
JMS
IMS
Resource
Adapter
Mainframe
CICS
IMS
Queue
Database
DO
DO
DO
Java
Domain
Objects
Resource
Collections
Individual
Resources
GET
PUT
DELETE
GET
POST
Service export
(loosely-coupled
mapping)
REST Service
Interface
Service
Implementation
Client App
HTTP
Client
library
Browser
HTTP
Native
Protocols
Servlet, Restlet,
JSR 311
annotations
Legacy
Resources
If using Java, a web container is sufficient to host domain objects. There is no need for an
EJB container. The domain model represented by these domain objects may be translated
to the REST service interface using servlets, restlets or the newer JSR 311 annotations.
Client applications need an HTTP Client library to consume these services.
29. Industry support for REST
New Java standard to expose REST services through annotations:
JSR 311
REST implementations:
IBM – Project Zero (PHP based REST server)
Microsoft – Astoria (.NET implementation)
Sun – Jersey (JSR 311 implementation)
WSO2 – Mashup Server (JavaScript-based server)
REST APIs:
Amazon eCommerce API
eBay Developer API
Yahoo! Web Service API
30. But why is REST so much simpler than SOAP/WS-*?
From one angle, any SOA implementation is just a means of moving
XML documents around, because XML documents formalise the
contract between components in a technology-neutral way.
SOAP/WS-* defines one kind of “plumbing” to move XML document
payloads around.
REST defines another kind of plumbing. The only known
implementation of REST is based on HTTP. This has proven to be
sufficient for virtually every enterprise use case.
SOAP places unnecessary emphasis on transport-neutrality. Transport-
neutrality is a feature with no practical benefit. The downsides of
transport neutrality are (1) a failure to exploit the many useful
features of the HTTP protocol and (2) a necessity to reinvent the same
features at a higher level of the stack.
New infrastructural components are required to understand and speak
the SOAP protocol. Such components already exist for the REST
protocol (HTTP), i.e., web servers.
31. “Things should be as simple as possible, but no
simpler” - Albert Einstein
Salesman: “This machine will cut your work in half.”
Customer: “Fine, I'll take two!”
REST is not for the intellectually lazy. It demands rigour in design.
The XML documents corresponding to the various service contracts
must be carefully designed. The data modelling effort remains
significant.
But fortunately, that is the only major component in designing and
building RESTian systems.
REST provides much simpler plumbing, so the complexity of the
infrastructure and the related configuration effort are dramatically
reduced.
In other words, REST makes SOA simpler by eliminating needless
complexity.
32. What REST will not do for you
Tasks that still need to be done:
Need for domain data modelling does not go away
Need for service contract does not go away, must decide
what resource abstractions to expose
No built-in security model, need to leverage SSL or IPSec
at wire protocol level or implement bespoke end-to-end
security model at payload level.
No built-in reliability model, must rely on design patterns
to achieve same outcome (e.g., idempotence)
Governance tasks still remain, although REST, being
“web style”, is inherently more federation-friendly
33. Conclusion
SOA design need not be hard. There are a few simple and
basic principles that need to be applied consistently
(fundamentally, it's about loose coupling between
systems).
These principles are harder to apply with the SOAP/WS-*
model.
The REST style involves an order of magnitude less
complexity than SOAP/WS-*. Everything is simpler – the
conceptual model, the infrastructural components, the
tooling, the metadata required, the level of governance,
etc.
The biggest impediment to the adoption of REST:
“Fear of the unknown”
34. References and further reading
1. How I explained REST to my wife
http://tomayko.com/articles/2004/12/12/rest-to-my-wife
2. REST for Toddlers (HTTP Status Codes explained)
http://diveintomark.org/archives/2006/12/07/rest-for-toddlers
3. REST Eye for the SOA Guy
http://dsonline.computer.org/portal/site/dsonline/
menuitem.9ed3d9924aeb0dcd82ccc6716bbe36ec/index.jsp?&
pName=dso_level1&path=dsonline/2007/01&file=w1tow.xml&xsl=article.xsl (or do a Google search on the title)
4. A Brief Introduction to REST
http://www.infoq.com/articles/rest-introduction
5. The Lost Art of Separating Concerns
http://www.infoq.com/articles/separation-of-concerns
6. Common REST mistakes
http://www.prescod.net/rest/mistakes/
7. Sample REST APIs from the real world:
a. Blinksale (a Paypal-like service):
http://www.blinksale.com/api
b. Backpack (a Travellers guide):
http://www.backpackit.com/api/
c. Assembla (Development and Issue Management Tool vendor):
https://www.assembla.com/wiki/show/breakoutdocs/Assembla_REST_API
d. WSO2 Registry (and Repository):
http://wso2.org/projects/registry
e. Mule Galaxy SOA Governance Tool:
http://www.mulesource.com/products/galaxy.php