Jetty’s HttpClient is a fast, scalable, asynchronous implementation of a HTTP client.
But it is even more.
Jetty’s HttpClient provides a high level API with HTTP semantic. This means that your applications will be able to perform HTTP requests and receive HTTP responses with a rich API. For example, you can use HttpClient to perform REST requests from the client or from within your web application to third party REST services.
Jetty’s HttpClient provides also pluggable transports. This means that the concept of a HTTP request and response is translated by HttpClient to SPDY, FastCGI, HTTP/1.1 or other protocols and transported over the network in SPDY, FastCGI and HTTP/1.1 formats, in a way that is totally transparent for the application, which will only see a high level HTTP request and a response.
Applications will get improved performance when using more performant transports.
The new addition in Jetty 9.3 is a HTTP/2 transport for HttpClient, replacing the SPDY transport.
This means that now HttpClient can talk to a regular HTTP/1.1 server, or to a FastCGI server that serves PHP pages, or to a HTTP/2 server transparently.
The HTTP/2 specification is in its final phases, so the HTTP/2 protocol is now stable and well supported: Firefox, Chrome, Internet Explorer 11 already supports HTTP/2, and as the time passes they will be enabling HTTP/2 by default (some already have).
And it’s not only browsers and servers such as Google, Twitter, etc.: also tools and libraries such as curl and nghttp2, among many others.
The Jetty project implemented HTTP/2 since June 2014 and this very website has been served using Jetty’s HTTP/2 implementation for now over 6 months, helping to finalize the interoperability among different implementations.
You are probably already reading this blog entry served via HTTP/2, if you are using a recent browser.
Contact us if you are interested in deploying HTTP/2 in your infrastructure and benefit from the performance improvements that it brings.
Tag: jetty
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HTTP/2 Support for HttpClient
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Phasing out SPDY support
Now that the HTTP/2 specification is in its final phases of approval, big players announced that they will remove support for SPDY in favor of long term support of HTTP/2 (Chromium blog). We expect others to follow soon.
Based on this trend and feedback from users the Jetty Project is announcing that it will drop support for SPDY in Jetty 9.3.x, replacing its functionalities with HTTP/2. We have milestone builds available for Jetty 9.3.0 now if you would like to try them out, they can be downloaded through Maven Central now. A new milestone release will be released shortly followed by a full release once the specification is finalized.
The SPDY protocol will remain supported in the Jetty 9.2.x series, but no further work will be done on it unless it is sponsored by a client. This will allow us to concentrate fully on a first class quality implementation of HTTP/2.
Along these same lines, Jetty 9.3 will drop support for NPN (the TLS Next Protocol Negotiation Extension), replacing its functionalities with ALPN (the TLS Application Layer Protocol Negotiation Extension, RFC 7301). NPN should remain supported in the Jetty 9.2.x series, and updated as new JDK 7 versions will be released.
Contact us if you are interested in migrating your existing SPDY solutions to HTTP/2. -
HTTP/2 Interoperability and HTTP/2 Push
Following my previous post, several players tried their HTTP/2 implementation of draft 14 (h2-14) against webtide.com.
A few issues were found and quickly fixed on our side, and this is very good for interoperability.
Having worked many times at implementing specifications, I know that different people interpret the same specification in slightly different ways that may lead to incompatibilities.
@badger and @tatsuhiro_t reported thatcurl + nghttp2is working correctly against webtide.com.
On the Firefox side, @todesschaf reported a couple of edge cases that were fixed, so expect a Firefox nightly soon (if not already out?) that supports h2-14.
We are actively working at porting the SPDY Push implementation to HTTP/2, and Firefox should already support HTTP/2 Push, so there will be more interoperability testing to do, which is good.
This work is being done in conjunction with an experimental Servlet API so that web applications will be able to tell the container what resources should be pushed. This experimental push API is scheduled to be defined by the Servlet 4.0 specification, so once again the Jetty project is leading the path like it did for async Servlets, SPDY and SPDY Push.
Why you should care about all this ?
Because SPDY Push can boost your website performance, and more performance means more money for your business.
Interested ? Contact us. -
HTTP/2 Last Call!
The IETF HTTP working group has issued a last call for comments on the proposed HTTP/2 standard, which means that the process has entered the final stage of open community review before the current draft may become an RFC. Jetty has implemented the proposal already and this website is running it already! There is a lot of good in this proposed standard, but I have some deep reservations about some bad and ugly aspects of the protocol.
The Good
HTTP/2 is a child born of the SPDY protocol developed by Google and continues to seek the benefits that have been illuminated by that grand experiment. Specifically:
- The new protocol supports the same semantics as HTTP/1.1 which was recently clarified by RFC7230. This will allow most of the benefits of HTTP/2 to be used by applications transparently simply by upgrading client and server infrastructure, but without any application code changes.
- HTTP/2 is a multiplexed protocol that allows multiple request/response streams to share the same TCP/IP connection. It supports out of order delivery of responses so that it does not suffer from the same Head of Line Blocking issues as HTTP/1.1 pipeline did. Clients will no longer need multiple connections to the same origin server to ensure good quality of service when rendering a page made from many resources, which means a very significant savings in resources needed by the server and also reduces the sticky session problems for load balancers.
- HTTP headers are very verbose and highly redundant. HTTP/2 provides an effective compression algorithm (HPACK) that is tailored to HTTP and avoids many of the security issues with using general purpose compression algorithms over TLS connections. Reduced header size allows many requests to be sent over a newly opened TCP/IP connection without the need to wait for it’s congestion control window to grow to the capacity of the link. This significantly reduces the number of network round trips required to render a page.
- HTTP/2 supports pushed resources, so that an origin server can anticipate requests for associated resources and push them to the clients cache, again saving further network round trips.
You can see from these key features, that HTTP/2 is primarily focused on improving the speed to render a page, which is (as the book of speed points out) a good focus to have. To a lesser extent, the process has also considered through put and server resources, but these have not been key drivers and indeed data rates may even suffer under HTTP/2 and servers need to commit more resources to each connection which may consume much of the savings from fewer connections.
The Bad
While the working groups was chartered to address the misuse of the underlying transport occurring in HTTP/1.1 (eg long polling), it did not make much of the suggestion to coordinate with other working groups regarding the possible future extension of HTTP/2.0 to carry WebSockets semantics. While a websocket over http2 draft has been written, some of the features that draft referenced have subsequently been removed from HTTP/2 and the protocol is primarily focused on providing HTTP semantics.
The proposed protocol does not have a clear separation between a framing layer and the HTTP semantics that can be carried by that layer. I was expecting to see a clear multiplexed, flow controlled framing layer that could be used for many different semantics including HTTP and webSocket. Instead we have a framing protocol aimed primarily at HTTP which to quote the drafts editor:
“What we’ve actually done here is conflate some of the stream control functions with the application semantics functions in the interests of efficiency” — Martin Thomson 8/May/2014
I’m dubious there are significant efficiencies from conflating layers, but even it there are, I believe that such a design will make it much harder to carry WebSocket or other new web semantics over the http2 framing layer. HTTP semantics are hard baked into the framing so intermediaries (routers, hubs, load balancers, firewalls etc.) will be deployed that will have HTTP semantic hard wired. The only way that any future web semantic will be able to be transported over future networks will be to use the trick of pretending to be HTTP, which is exactly the kind of misuse of the underlying transport, that HTTP/2 was intended to address. I know it is difficult to generalise from one example, but today we have both HTTP and WebSocket semantics widely used on the web, so it would have been sensible to consider both examples equally when designing the next generation web framing layer.
An early version of the draft had a header compression algorithm that was highly stateful which meant that a single streams headers had to be encoded/decoded in total before another streams headers could be encoded/decoded. Thus a restriction was put into the protocol to prevent headers being transmitted as multiple frames interleaved with other streams frames. Furthermore, headers are excluded from the multiplexing flow control algorithm because once encoded transmission cannot be delayed without stopping all other encoding/decoding.
The proposed standard has a less stateful compression algorithm so that it is now technically possible to interleave other frames between a fragmented header. It is still not possible to flow control headers, but there is no technical reason that a large header should prevent other streams from progressing. However a concern about denial of service was raised in the working group, and while I argued that it was no worse than without interleaving, the working group was unable to reach consensus to remove the interleaving restriction.
Thus HTTP/2 has a significant incentive for applications to move large data into headers, as this data will effectively take control of the entire multiplexed connection and will be transmitted at full network speed regardless of any http2 flow control windows or other streams that may need to progress. If applications are take up these incentives, then the quality of service offered by the multiplexed connection will suffer and the Head of Line Blocking issue that HTTP/2 was meant to address will return as large headers will hit TCP/IP flow control and stop all streams. When this does happen, clients are likely to do exactly as they did with HTTP/1.1 and ignore any specifications about connection limits and just open multiple connections, so that requests can overtake others that are using large headers to try to take an unfair proportion of a shared connection. This is a catastrophic scenario for servers as not only will we have the increased resource required by HTTP/2 connections, but we will also have the multiple connections required by HTTP/1.
I would like to think that I’m being melodramatic here and predicting a disaster that will never happen. However the history from HTTP/1.1 is that speed is king and that vendors are prepared to break the standards and stress the servers so that applications appear to run faster on their browsers, even if it is only until the other vendors adopt the same protocol abuse. I think we are needlessly setting up the possibility of such a catastrophic protocol fail to protect against a DoS attack vector that must be defended anyway.
The Ugly
There are many aspect of the protocol design that can’t be described as anything but ugly. But unfortunately even though many in the working group agree that they are indeed ugly, the IETF process does not consider aesthetic appeal and thus the current draft is seen to be without issue (even though many have argued that the ugliness means that there will be much misunderstanding and poor implementations of the protocol). I’ll cite one prime example:
A classic case of design ugliness is the END_STREAM flag. The multiplexed streams are comprised of a sequence of frames, some of which can carry the END_STREAM flag to indicate that the stream is ending in that direction. The draft captures the resulting state machine in this simple diagram:
+--------+ PP | | PP ,--------| idle |--------. / | | \ v +--------+ v +----------+ | +----------+ | | | H | | ,---| reserved | | | reserved |---. | | (local) | v | (remote) | | | +----------+ +--------+ +----------+ | | | ES | | ES | | | | H ,-------| open |-------. | H | | | / | | \ | | | v v +--------+ v v | | +----------+ | +----------+ | | | half | | | half | | | | closed | | R | closed | | | | (remote) | | | (local) | | | +----------+ | +----------+ | | | v | | | | ES / R +--------+ ES / R | | | `----------->| |<-----------' | | R | closed | R | `-------------------->| |<--------------------' +--------+ H: HEADERS frame (with implied CONTINUATIONs) PP: PUSH_PROMISE frame (with implied CONTINUATIONs) ES: END_STREAM flag R: RST_STREAM frameThat looks simple enough, a stream is open until an END_STREAM flag is sent/received, at which stage it is half closed, and then when another END_STREAM flag is received/sent the stream is fully closed. But wait there’s more! A stream can continue sending several frame types after a frame with the END_STREAM flag set and these frames may contain semantic data (trailers) or protocol actions that must be acted on (push promises) as well as frames that can just be ignored. This introduces so much complexity that the draft requires 7 paragraphs of dense text to specify the frame handling that must be done once your in the Closed state! It is as if TCP/IP had been specified without CLOSE_WAIT. Worse yet, it is as if you could continue to send urgent data over a socket after it has been closed!
This situation has occurred because of the conflation of HTTP semantics with the framing layer. Instead of END_STREAM being a flag interpreted by the framing layer, the flag is actually a function of frame type and the specific frame type must be understood before the framing layer can consider any flags. With HTTP semantics, it is only legal to end some streams on some particular frame types, so the END_STREAM flag has only been put onto some specific frame types in an attempt to partially enforce good HTTP frame type sequencing (in this case to stop a response stream ending with a push promise). It is a mostly pointless attempt to enforce legal type sequencing because there are an infinite number of illegal sequences that an implementation must still check for and making it impossible to send just some sequences has only complicated the state machine and will make future non-HTTP semantics more difficult. It is a real WTF moment when you realise that valid meta-data can be sent in a frame after a frame with END_STREAM and that you have to interpret the specific frame type to locate the actual end of the stream. It is impossible to write general framing code that handles streams regardless of their type.
The proposed standard allows padding to be added to some specific frame types as a “security feature“, specifically to address “attacks where compressed content includes both attacker-controlled plaintext and secret data (see for example, [BREACH])“. The idea being that padding can be used to hide the affects of compression on sensitive data. But as the draft says “padding is a security feature; as such, its use demands some care” and it turns out to be significant care that is required:
- “Redundant padding could even be counterproductive.”
- “Correct application can depend on having specific knowledge of the data that is being padded.”
- “To mitigate attacks that rely on compression, disabling or limiting compression might be preferable to padding as a countermeasure.”
- “Use of padding can result in less protection than might seem immediately obvious.”
- “At best, padding only makes it more difficult for an attacker to infer length information by increasing the number of frames an attacker has to observe.”
- “Incorrectly implemented padding schemes can be easily defeated.”
So in short, if you are a security genius with precise knowledge of the payload then you might be able to use padding, but it will only slightly mitigate an attack. If you are not a security genius, or you don’t know your what your application payload data is (which is just about everybody), then don’t even think of using padding as you’ll just make things worse. Exactly how an application is meant to tunnel information about the security nature of its data down to the frame handling code of the transport layer is not indicated by the draft and there is no guidance to say what padding to apply other than to say don’t use randomized padding.
I doubt this feature will ever be used for security, but I suspect that it will be used for smuggling illicit data through firewalls.
What Happens Next?
This blog is not a call others to voice support for these concerns in the working group. The IETF process does not work like that, there are no votes and weight of numbers does not count. But on the other hand don’t let me discourage you from participating if you feel you have something to contribute other than numbers.
There has been a big effort by many in the working group to address the concerns that I’ve described here. The process has given critics fair and ample opportunity to voice concerns and to make the case for change. But despite months of dense debate, there is no consensus in the WG that the bad/ugly concerns I have outlined here are indeed issues that need to be addressed. We are entering a phase now where only significant new information will change the destiny of http/2, and that will probably have to be in the form of working code rather than voiced concerns (an application that exploits large headers to the detriment of other tabs/users would be good, or a DoS attack using continuation trailers).
Finally, please note that my enthusiasm for the Good is not dimmed by my concerns for the Bad and Ugly. The Jetty team is well skilled to deal with the Ugly for you and we’ll do our best to hide the Bad as well, so you’ll only see the benefits of the Good. Jetty-9.3 is currently available as a development branch and currently supports draft 14 of HTTP/2 and this website is running on it!. Work is under way on the current draft 14 and that should be supported in a few days. We are reaching out to users and clients who would like to collaborate on evaluating the pros/cons of this emerging standard.
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HTTP/2 draft 14 is live !
Greg Wilkins (@gregwilkins) and I (@simonebordet) have been working on implementing HTTP/2 draft 14 (h2-14), which is the draft that will probably undergo the “last call” at the IETF.
We will blog very soon with our opinions about HTTP/2 (stay tuned, it’ll be interesting!), but for the time being Jetty proves once again to be a trailblazer when it comes with new web technologies and web protocols.
Jetty started to innovate with Jetty Continuations, that were standardized (with improvements) into Servlet 3.0.
Jetty was one of the first Java server to offer support for asynchronous I/O back in 2006 with Jetty 6.
In 2012 we were the first Java server to implement SPDY, we have written libraries that provide support for NPN in Java (that are now used by many other Java servers that provide SPDY support). We also were the first to implement a completely automatic way of leveraging SPDY Push, that can boost your web site performance.
Today, to my knowledge, we are again the first Java server exposing the implementation of the HTTP/2 protocol, draft 14, live on our own website.
Along with HTTP/2 support, that will be coming in Jetty 9.3, we have also implemented a library that provides support for ALPN in Java (the successor of NPN), allowing every Java application (client or server) to implement HTTP/2 over SSL. This library is already available in the Jetty 9.2.x series. We want other implementers (client and server) to test our HTTP/2 implementation in order to generate feedback about HTTP/2 that can be reported at the IETF.
As of today, both Mozilla Firefox and Google Chrome only support HTTP/2 draft 13 (h2-13). They are keeping the pace at implementing new drafts, so expect both browsers to offer draft 14 support in matter of days (in their nightly/unstable versions). When that will happen, you will be able to use those browsers to connect to our HTTP/2 enabled website.
The Jetty project offers not only a server, but a HTTP/2 client as well. You can take a look at how it’s used to connect to a HTTP/2 server here.
Where is it ? https://webtide.com.
Lastly, contact us for any news or information about what Jetty can do for you in the realms of async I/O, PubSub over the web (via CometD), SPDY and HTTP/2.
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Jetty 9.1.4 Open Sources FastCGI Proxy
I wrote in the past about the support that was added to Jetty 9.1 to proxy HTTP requests to a FastCGI server.
A typical configuration to serve PHP applications such as WordPress or Drupal is to put Apache or Nginx in the front and have them proxy the HTTP requests to, typically,php-fpm(a FastCGI server included in the PHP distribution), which in turn runs the PHP scripts that generate HTML.
Jetty’s support for FastCGI proxying has been kept private until now.
With the release of Jetty 9.1.4 it is now part of the main Jetty distribution, released under the same license (Apache License or Eclipse Public License) as Jetty.
Since we like to eat our own dog food, Jetty is currently serving the pages of this blog (which is WordPress) using Jetty 9.1.4 and the newly released FastCGI module.
And it is doing so via SPDY, rather than HTTP, allowing you to serve Java EE Web Applications and PHP Web Applications from the same Jetty instance and leveraging the benefits that the SPDY protocol brings to the Web.
For further information and details on how to use this new module, please check the Jetty FastCGI documentation.
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WordPress & Jetty: perfect fit
I posted a while back about the capability of Jetty 9.1’s
HttpClientto speak HTTP over different transports: by default HTTP, but we also provide a SPDY implementation, where the HTTP requests and responses are carried using the SPDY transport rather than the HTTP transport.
Another transport that is able to carry HTTP requests and responses is FastCGI.
The neat feature about FastCGI is that it is the default way to deploy PHP applications: fire up a proxy server (usually Apache or Nginx) in the front and proxy requests/responses to the FastCGI server (usually the PHP FastCGI Process Manager, orphp-fpm).
In this way you can deploy the most used PHP frameworks like WordPress, Drupal and others.
And you are not limited to PHP: FastCGI allows you to easily deploy other dynamic web languages and frameworks such as Django (Python-based), Rails (Ruby-based) and others.
We are happy to announce that Jetty 9.1 can now proxy to FastCGI, enabling deployment of PHP frameworks.
Why this is good, and how different it is from having – say – Apache or Nginx in the front instead of Jetty ?
The first and foremost reason is that Jetty is the only server that supports SPDY Push.
SPDY Push is the biggest performance improvement you can make to your website, without a single change to the application being served, be it a Java web application or WordPress.
Watch our video that shows how the SPDY Push feature that Jetty provides makes a big performance difference.
The second reason is that SPDY version 2 is being deprecated really fast in favor of SPDY version 3 or greater.
Browsers will not speak SPDY/2 anymore, basically reverting your website to HTTPS behaviour, losing all the SPDY benefits if your server does not support SPDY 3 or greater.
As of the time of this writing, only servers like Apache or Jetty implement SPDY version 3 or later of the SPDY protocol, while Nginx only implements SPDY version 2.
At the Jetty Project we like to eat our own dogfood, so the blog site you are reading is WordPress served via Jetty.
If you’re using Firefox or Chrome, just open the browser network console, and you will see something like this:
As you can see from the response headers, the response is served by Jetty (Server: Jetty(9.1.0.v20131115)) from PHP (X-Powered-By: PHP/5.5.3-1ubuntu2).
Of course, since both Jetty 9.1’s server andHttpClientare fully asynchronous, you have a very scalable solution for your PHP-enabled website: currently the JVM that runs this very website only uses 25 MiB of heap.
And of course you get all the SPDY performance improvements over HTTP, along with Jetty’s unique SPDY Push features.
This is good for cloud vendors too, since they can run Jetty and expose PHP applications with a minimal amount of resources, high scalability, and unique features like SPDY Push.
FastCGI for Jetty is sponsored by Intalio. If you are interested in knowing more about how Jetty can speed up your website or how to setup your PHP web application in Jetty, contact us or send an email to Jesse McConnell. -
Pluggable Transports for Jetty 9.1's HttpClient
In Jetty 9, the
HttpClientwas completely rewritten, as we posted a while back.
In Jetty 9.1, we took one step forward and we made Jetty’sHttpClientpolyglot. This means that now applications can use the HTTP API and semantic (“I want to GET the resource at the http://host/myresource URI”) but can now choose how this request is carried over the network.
Currently, three transports are implemented: HTTP, SPDY and FastCGI.
The usage is really simple; the following snippet shows how to setupHttpClientwith the default HTTP transport:// Default transport uses HTTP HttpClient httpClient = new HttpClient(); httpClient.start();
while the next snippet shows how to setup
HttpClientwith the SPDY transport:// Using the SPDY transport in clear text // Create the SPDYClient factory SPDYClient.Factory spdyClientFactory = new SPDYClient.Factory(); spdyClientFactory.start(); // Create the SPDYClient SPDYClient spdyClient = spdyClientFactory.newSPDYClient(SPDY.V3); // Create the HttpClient transport HttpClientTransport transport = new HttpClientTransportOverSPDY(spdyClient); // HTTP over SPDY ! HttpClient httpSPDYClient = new HttpClient(transport, null); httpSPDYClient.start(); // Send request, receive response ContentResponse response = httpSPDYClient.newRequest("http://host/path") .method("GET") .send();This last snippet allows the application to still use the HTTP API, but have the request and the response transported via SPDY, rather than HTTP.
Why this is useful ?
First of all, more and more websites are converting to SPDY because it offers performance improvements (and if you use Jetty as the server behind your website, the performance improvements can be stunning, check out this video).
This means that with a very simple change in theHttpClientconfiguration, your client application connecting to servers can benefit of the performance boost that SPDY provides.
If you are usingHttpClientfor server-to-server communication, you can use SPDY in clear text (rather than encrypted) to achieve even more efficiency because there is no encryption involved. Jetty is perfectly capable of speaking SPDY in clear text, so this could be a major performance win for your applications.
Furthermore, you can parallelize HTTP requests thanks to SPDY’s multiplexing rather than opening multiple connections, saving network resources.
I encourage you to try out these features and report your feedback here in the comments or on the Jetty mailing list. -
Jetty, SPDY and HAProxy
The SPDY protocol will be the next web revolution.
The HTTP-bis working group has been rechartered to use SPDY as the basis for HTTP 2.0, so network and server vendors are starting to update their offerings to include SPDY support.
Jetty has a long story of staying cutting edge when it is about web features and network protocols.- Jetty first implemented web continuations (2005) as a portable library, deployed them successfully for years to customers, until web continuations eventually become part of the Servlet 3.0 standard.
- Jetty first supported the WebSocket protocol within the Servlet model (2009), deployed it successfully for years to customers, and now the WebSocket APIs are in the course of becoming a standard via JSR 356.
Jetty is the first and today practically the only Java server that offers complete SPDY support, with advanced features that we demonstrated at JavaOne (watch the demo if you’re not convinced).
If you have not switched to Jetty yet, you are missing the revolutions that are happening on the web, you are probably going to lose technical ground to your competitors, and lose money upgrading too late when it will cost (or already costs) you a lot more.
Jetty is open source, released with friendly licenses, and with full commercial support in case you need our expertise about developer advice, training, tuning, configuring and using Jetty.
While SPDY is now well supported by browsers and its support is increasing in servers, it is still lagging a bit behind in intermediaries such as load balancers, proxies and firewalls.
To exploit the full power of SPDY, you want not only SPDY in the communication between the browser and the load balancer, but also between the load balancer and the servers.
We are actively opening discussion channels with the providers of such products, and one of them is HAProxy. With the collaboration of Willy Tarreau, HAProxy mindmaster, we have recently been able to perform a full SPDY communication between a SPDY client (we tested latest Chrome, latest Firefox and Jetty’s Java SPDY client) through HAProxy to a Jetty SPDY server.
This sets a new milestone in the adoption of the SPDY protocol because now large deployments can leverage the goodness of HAProxy as load balancer *and* leverage the goodness of SPDY as well as provided by Jetty SPDY servers.
The HAProxy SPDY features are available in the latest development snapshots of HAProxy. A few details will probably be subject to changes (in particular the HAProxy configuration keywords), but SPDY support in HAProxy is there.
The Jetty SPDY features are already available in Jetty 7, 8 and 9.
If you are interested in knowing how you can use SPDY in your deployments, don’t hesitate to contact us. Most likely, you will be contacting us using the SPDY protocol from your browser to our server 🙂
