Planet GStreamer

Another week, another panel refresh.

Rather than the 2-pane approach, and a separate setup interface we used to have, we've gone for a single pane device list, as you've probably seen on your smartphone.



We also do away with the "Discoverable" switch (your computer will be visible when this panel is opened, invisible if not), and nearby devices will show up at the bottom of the list. Simply click on one to set it up.

Clicking on an already setup device will bring up the properties, allowing you to connect to the device if necessary, or link to related preferences.

Over the last few days a few new GStreamer were added to latest GIT, and will be part of the 1.3/1.4 releases.

OpenNI2 – 3D sensors support

Miguel Casas-Sanchez worked on implementing a source element for the OpenNI2 API, which supports the Kinect camera of the XBox and some other cameras that provide depth information as another channel. This is not to be confused with stereoscopic videos as supported by some codecs and used in cinema, which uses two different frames from slightly different angles and creates a 3D image from that.

This source element handles dumps of the camera input to files, and also capturing from cameras directly. Currently the output of it is either RGB (without depth information), 16bit grayscale (only depth information) or RGBA (with depth information in the alpha channel). This can be configured with the “sourcetype” property right now. At a later time we should try to define a proper interface for handling depth information, especially something that does not feel completely contradictory with the stereoscopic video API. Maybe there could be just another plane for the depth information in a GstMeta.

The plugin is available in gst-plugins-bad GIT.

RTP over TCP

One question that was asked often in the past is how to stream RTP over a TCP connection. As RTP packets are expected to be sent over a datagram protocol, like UDP, and TCP provides a stream protocol, it is necessary to collect a complete packet at the receiver side and then pass this onwards. RTP has no size information in the packets, so an additional framing protocol is required on top of RTP. Fortunately there’s an RFC which defines a very simple one that is used in practice: RFC4571. Thanks to Olivier Crête for mentioning this RFC on the gstreamer-devel mailinglist. The framing protocol is very simple, it’s defined as just pre-pending a 16 bit unsigned, big-endian integer in front of each RTP or RTCP packet.

Yesterday I wrote two simple elements for this RFC implemented and integrated them into gst-plugins-good GIT.

They can for example be used like this:

gst-launch-1.0 audiotestsrc ! “audio/x-raw,rate=48000″ ! vorbisenc ! rtpvorbispay config-interval=1 ! rtpstreampay ! tcpserversink port=5678

gst-launch-1.0 tcpclientsrc port=5678 host=127.0.0.1 do-timestamp=true ! “application/x-rtp-stream,media=audio,clock-rate=48000,encoding-name=VORBIS” ! rtpstreamdepay ! rtpvorbisdepay ! decodebin ! audioconvert ! audioresample ! autoaudiosink

A more elaborate solution could also use RTCP communication between the sender and receiver. RTCP can also be passed through the rtpstreampay and rtpstreamdepay elements the same way.

For anything more complicated you should consider looking into RTSP though as it is much more flexible, feature-rich and allows exchanging the stream configurations automatically, and it also allows streams to be delivered via TCP (or UDP unicast/multicast). GStreamer has a source plugin and a server library for receiving or serving RTSP streams.

OpenEXR – HDR image formats

Another thing that I worked on (and still do) is an OpenEXR decoder plugin. OpenEXR is a HDR image format, but unfortunately we don’t have support for any HDR-compatible raw video format in GStreamer… yet! The OpenEXR decoder element is inside gst-plugins-bad GIT now but internally converts the 16 bit floating point color components to 16 bit integers, choosing 1.0 as clipping point. Once there’s consensus about how to expose such raw video formats in GStreamer (see Bugzilla #719902), support for the 16 bit floating point RGBA format should be easy to add.

I typically don’t listen to podcasts or watch talk shows, but the 29nd episode of the 2nd season of the Linux Action Show was referred to me and it does have a very interesting part where they discuss the usability and privacy issues around the latest iteration of Canonical’s “Unity” interface. The ten minutes where these guys discussed the matter were surprisingly thought-provoking even for someone like me who was already aware of privacy issues.

The part where they discuss the usability problems and relevance of “smart scopes” search results is between 51 minutes 40 seconds and 55 minutes.

The part where they discuss the privacy implications is between 55 minute 30 seconds and the 1 hour 1min mark, and that’s the one I’m particularly interested in here. It feels important enough for me to transcribe bits of it for you here:

“[...] they track what you search for, and the IP it came from. [Canonical] also state in their terms of service that if they’re served a warrant, they will hand that information over. [...] I was more comfortable with it before Edward Snowden existed (sic). And now what I know, where you have companies like Lavabit, where federal authorities will come in with outrageous warrants… and so… there was just a recent crackdown on Tor and so, right?

[...] Here’s the thing: in a post-Snowden world, if I decide to run Tor Browser, everytime I type “Tor browser” into this, there is a ping that goes off to Canonical’s servers and says “the person at this IP address just launched Tor”. Now, if I’m the federal authorities, I can go subpoena these records and I can say “now look, we saw this Tor traffic, and we saw your computer launch Tor at this time, let’s go get a warrant and search through Chris’ files because we saw, when we subpoena’d Canonical’s information, that he launched the Tor browser on his computer, thereby giving us justifiable means to search his whole machine.

Why did they even put themselves into that position?!

[...] The main problem is… it gives a record of the commands I launched on my computer. It’s a keylogger.”

This depiction is so simple, yet so elegant and powerful in explaining the issue at hand! It makes me glad to be running a desktop environment that aims to spearhead privacy by default and by principle, governed by the community and a registered non-profit organization rather than controlled by a single entity keen on turning me into the product to be monetized out of desperation.

Sure, you could say privacy does not exist, but the local computing experience of an open-source desktop operating system is an entirely different matter than the world-wide web. Locally run open-source software is the last bastion, the one area where we can put our trust and must hold our ground.

The Pitivi project is looking for someone who loves teaching/writing, to fill the position of “documentation specialist” among our team! The documentation specialist will be responsible for updating our fantastic user manual (online version here) based on release notes of 0.91 and 0.92 as well as your own imagination/ideas for improvement.

The user manual is written in Mallard, but I can even accept contributions in plaintext (I would then do the markup myself). You only have to write it in English; other languages are handled by the hyperactive GNOME translation teams. You will receive:

• No pay
• No company-provided car, gym or insurance
• Praise, hugs, possibly some beers at events such as GUADEC
• Something great to put in your résumé/CV as a technical writer and contributor to open-source
• The feeling of a job well done in a project that matters for the world
• An autographed biography of Richard Stallman in French, if you’re into that sort of thing. I’m not even kidding, there’s a guy actually offering that as a perk on the Internet.
• A gentle entry into the world of contributing to Pitivi if you want to go further

Apply now on #pitivi on irc.freenode.net !

Rule number one: trust Google Maps. Rule number two: do not believe the locals’ knowledge of their own transportation system.

Stockholm is this big city that prides itself on having a great public transportation system. It sounds great. Until you find out at 1AM that everything shuts down at night. So here you are, in central station, with SL employees telling you “It’s closed, sorry. Get to the airport tomorrow”. That obviously won’t work with a flight that leaves at 6.

Let me restate my disbelief here: a city with four friggin’ airports has no 24/7 public transportation to get to its biggest airport. Except it does, but nobody knows about it, or they don’t believe it works. Bus 592 and 593 take you from some parts of downtown to Stockholm-Arlanda airport.

The reason I’m bothering to write a blog post about this is that I want to put this information out there; it was impossible for me (with a fair amount of googling skills) to be absolutely certain of the fare/pricing/payment system for bus 593 and bus 592. The SL’s website doesn’t tell you, Google doesn’t tell you, wikipedia and wikitravel don’t tell you, and all the locals I asked were convinced that it is impossible to travel to Arlanda with normal tickets. They will tell you to try to take the train instead.

I am living proof that it is possible, and I’m putting this blog post out there to let the rest of the world know when they search the Internet for two very simple questions:

• “Can you go to Arlanda with one ticket on a blue SL card?”: Yes. The night buses are really local buses, and since you’re boarding them in the (central) zone A, a normal ticket is enough. I had a blue RFID transportation card with only two tickets left; I used one for the subway, realized the transportation offering was rubbish, ran in ten directions asking various locals along the way, ran to the 593 bus stop I initially planned to go to, and confirmed there that it works fine with one normal ticket. So this turns out to be the cheapest way (also arguably the simplest) to get to the arlanda airport, although it takes a bit longer due to the many bus stops.
• “Can you pay with a credit card on the bus?”: No, I don’t think so. I did not see any cash or credit card machines on the bus, only SL “access” card machines.

Of course, the answer to the first question only applies to getting out of Stockholm towards the airport. Due to the zone system, I suspect that the other way around doesn’t work. And during daytime, buses 592/593 don’t exist.

Over the last few weeks I worked on a new GStreamer element: audiomixer. This new element is based on adder, i.e. it mixes multiple audio streams together and produces a single audio stream. It’s already merged into GIT master of the gst-plugins-bad module.

The main and important difference to adder is that it actually synchronizes the different audio streams against each other instead of just mixing samples together as they come while ignoring all timing information. This was a feature that was requested since a long time and in practice causes problems if streams are supposed to start at different times, have gaps or slightly different clock rates (and thus one is supposed to run a bit faster than the other). It’s also an important first step to properly support mixing of live streams. The video element for mixing, videomixer, properly implements synchronization since a few years now.

A very simple example to see the difference between both elements would be the following gst-launch command:

gst-launch-1.0 audiomixer name=mix
  mix. ! audioconvert ! audioresample ! autoaudiosink
  audiotestsrc num-buffers=400 volume=0.2 ! mix.
  audiotestsrc num-buffers=300 volume=0.2 freq=880 timestamp-offset=1000000000 ! mix.
  audiotestsrc num-buffers=100 volume=0.2 freq=660 timestamp-offset=2000000000 ! mix.

If you replace audiomixer by adder, you’ll hear all streams starting at the same time while with audiomixer they start with the correct offsets to each other.

So, what’s left to be done. Currently reverse playback/mixing is not support, that’s somewhere next on my todo list. Also the handling of flushing seeks and flushes in general on mixers (and muxers) is currently rather suboptimal, that’s something I’m working on next. As a side-effect this will also bring us one step nearer to proper mixing of live streams.

This week and next week I’m going to be in San Francisco and will attend the Foundations of Open Media Standards and Software (FOMS) workshop 2013. Thanks to Silvia Pfeiffer, the other organisers and the sponsors of the event (Google and brightcove) for making this possible by sponsoring me.

Topics that are going to be discussed are WebRTC, Web multimedia in general, open codecs and related topics and the list of attendees seems very diverse to me. I expect lots of interesting discussions and a few interesting and hopefully productive days

If anybody else is in that area currently and wants to meet for a coffee, beer or some food on the 2-3 days before and after FOMS, please write me a mail or use some other communication channel

As you might remember, GNOME 3.10 switched to using BlueZ 5.x as its Bluetooth backend.

Switching to BlueZ 5.x meant that the old obex-data-server (which was used in both the gvfs ObexFTP backend, and gnome-user-share) couldn't be used anymore. The previously stand-alone obexd was to be used.

Its API is quite different, and it obviously didn't get much testing apart from its target use case, the single-user phone case.

I fixed a number of bugs this week-end, which should make Obex Push server-side (sending files from your phone to your computer) work as expected.

Distributors' homework

First, distributors will need to do a bit of work for you:
- Ship and apply this (not yet upstreamed) patch if you don't have a systemd-based session, so that obexd can be started via D-Bus.
- And ship this patch to have obexd write to the user's cache dir by default.

With both of those patches to BlueZ and gnome-user-share 3.10.1, you should be golden.

Note that the first patch is also required if you want to send files using bluetooth-sendto.

ObexFTP

You'll notice that we didn't mention ObexFTP yet, but we'll do, one last time. ObexFTP support client side hasn't seen any updates for a couple of years, and the server side support for it in obexd didn't match our expectations (such as the inability to kill existing, already made connections).

So ObexFTP support was never finished porting and re-enabled in gnome-user-share. And given that apart from computers and very few phones, the client side support was lacking, we decided to kill the support for it in gnome-user-share.



TL;DR

ObexPush server support is fixed in gnome-user-share 3.10.1, and ObexFTP server support is gone.

Overview

CuteSpotify makes it possible to listen to your Spotify songs on Ubuntu Touch. It’s based on MeeSpot (a MeeGo Spotify client), which I’ve updated to make use of Qt5 and Ubuntu’s QML components. It’s still a little rough around the edges but most of the core functionality is in place now.

One particular problem to look out for is that because of the way Ubuntu Touch currently handles applications CuteSpotify has to be kept in the foreground and the phone has to be kept switched on for music to play (otherwise the application gets suspended). Approaches for handling applications that need to keep running are currently being debated, so hopefully that won’t be the case in future version of Ubuntu Touch.

As a temporary workaround, if your phone is in developer mode (achieved by connecting it up to the Ubuntu SDK) you can run “sudo service powerd stop” (default password is phablet) to stop the phone from going to sleep while you’re listening to music, then “sudo service powerd start” to resume normal power management when you’re done. (See popey’s comment for an alternative method).

Video

Video of CuteSpotify running on Ubuntu Touch

Installation

To install CuteSpotify on Ubuntu Touch simply search for “CuteSpotify” on your phone and it should appear.

Source

The source code for CuteSpotify can be found here: https://github.com/Elleo/cutespotify

The GStreamer team is pleased to announce a new release of the stable 1.2 release series. The 1.2 release series is adding new features on top of the 1.0 series and is part of the API and ABI-stable 1.x release series of the GStreamer multimedia framework that contains new features.

Binaries for Windows, Mac OS X and Android will be provided in the next days and will be announced separately.

Check out the release notes for GStreamer core, gst-plugins-base, gst-plugins-good, gst-plugins-ugly, gst-plugins-bad, or gst-libav, or download tarballs for gstreamer, gst-plugins-base, gst-plugins-good, gst-plugins-ugly, gst-plugins-bad, or gst-libav,

Check the release announcement mail for details and the release notes above for a list of changes.

Also available are binaries for Android, iOS, Mac OS X and Windows.

October marked the end of my work at Collabora, doing marketing and business development. I am quite sad to part ways with many talented and enjoyable people I’ve grown fond of, but that’s life and I’m sure our paths will cross again.

Need a passionate open-source project manager, interaction designer or business developer with great insight of open-source technologies and communities? Hit me up as nekohayo on IRC (FreeNode or GIMPnet) or by mail at nekohayo at gmail dot com.

Overview

Eyrie is a music identification program that I originally created for the Nokia N9 but which I’ve now also ported to Ubuntu Touch. It works in a similar way to commercial applications like Shazam and SoundHound, listening to music through the phone’s microphone and then generating an acoustic fingerprint using the open source EchoPrint algorithm. Currently the EchoPrint database isn’t anywhere near as large as the various commercial offerings, so it won’t recognise everything, but it has reasonable coverage.

Video

Video of Eyrie running on Ubuntu Touch

Installation

To install Eyrie on Ubuntu Touch simply search for “Eyrie” on your phone and it should appear.

The past few weeks have been pretty crazy.

At the last minute, I ended up going to the GStreamer Conference in Edinburgh, thanks to the GStreamer project sponsoring my attendance. As always, it was a fantastic event and it was great to meet up with old friends and see great topics being discussed. I was pretty impressed by the amount of attendees too. I’m feeling guilty for having missed good talks while being dragged into hallway discussions or being hammered by jetlag, but our pals at Ubicast recorded everything so I should be able to catch up later. My good friend Luis summarized the event much better than I could, so I won’t go into detail here. Except that Thibault won a bottle of whiskey and was unable to claim it, so I picked it up and brought it back for him (I don’t hack on GStreamer itself, so I don’t need the whiskey):

After gstcon, I embarked on a pretty hectic journey throughout Europe, with the goal of prospecting sustainable development opportunities and to eventually crash at Mathieu Duponchelle’s home in order to spend time on Pitivi together.

Since I’m someone who tends to plan and optimize everything, hopping from city to city in a semi-improvised way over the past two weeks has been somewhat stressful. Especially the part where I found out the hard way that some capitals have their public transportation system to the airport shut down at night, or the part where I had to sleep on the floor in the entrance of the airport that was also closed at night even though you have flights departing before sunrise. That was fun. It is also a significant amount of transportation costs piling up (even though I’m an expert at minimizing them), so if you’d like to help offset some of the costs resulting from our current Pitivi activities, please feel free to tip a few bucks ;)

Managing and maintaining an established open-source project does not just mean coding: there is a lot of administrativia and planning involved, which has been consuming my free time lately. After discussions with Karen and Jim at the GNOME Montréal Summit, the post-GSoC stuff to deal with, the big research project I’ve been tackling and the research around the infrastructure needed for it, all on top of paperwork needing to be done at home during my absence, there was pretty much no time left for me to look at code. I somehow still managed to squeeze in a few commits to fix some blockers and a few trivial things, but that means that larger projects (even something as “simple” as reviewing a new set of icons) had to be renegotiated in my TODO list.

While staying with Mathieu in the past few days, we made some good progress on a big project coming up for Pitivi (more on that later) and released 0.92 to provide some fixes and polish over the earth-shattering 0.91. As you can see, this release comes just one month after the biggest release in years, so we are indeed aiming to get back onto a “release early, release often” cycle now. We hope you like it.

As the folks at gstreamer.com (not to be confused with the GStreamer project) are still at the old and unmaintained GStreamer 0.10 release series, I started to port all their tutorials and examples to 1.x. You can find the code here: http://cgit.freedesktop.org/~slomo/gst-sdk-tutorials/

This includes the generic tutorials and examples, and ones for iOS and Android. Over the past months many people wanted to try the 1.x binaries for iOS and Android and were asking for examples how to use them. Especially the fourth and fifth tutorials should help to get people started fast, you can find them here (Android) and here (iOS).

If there are any problems with these, please report them to myself or if you suspect any GStreamer bugs report them in Bugzilla. The XCode OS X project files and the Visual Studio project files are ported but I didn’t test them, please report if they work

This is the companion article for my talk at the GStreamer Conference 2013: The never-ending story: GStreamer and hardware integration

The topic of hardware integration into GStreamer (think of GPUs, DSPs, hardware codecs, OpenMAX IL, OpenGL, VAAPI, video4linux, etc.) was always a tricky one. In the past, in the 0.10 release series, it often was impossible to make full and efficient use of special hardware features and many ugly hacks were required. In 1.x we reconsidered many of these problems and tried to adjust the existing APIs, or add new APIs to make it possible to solve these problems in a cleaner way. Although all these APIs are properly documented in detail, what’s missing is some kind of high-level/overview documentation to understand how it all fits together, which API to use when for what. That’s what I’m trying to solve here now.

What’s new in GStreamer 1.0 & 1.2

The relevant changes in GStreamer 1.x for hardware integration are the much better memory management and control with the GstMemory and GstAllocator abstractions and GstBufferPool, the support for arbitrary buffer metadata with GstMeta, sharing of device contexts between elements with GstContext and the reworked (re-)negotiation and (re-)configuration mechanisms, especially the new ALLOCATION query. In the following I will explain how to use them in the context of hardware integration and how they all work together and will assume that you already know and understand the basics of GStreamer.

Special memory

The most common problem when dealing with special hardware and the APIs to use it is, that it requires the usage of special memory. Maybe there are some constraints on the memory (e.g. regarding alignment or physical contiguous memory is required), or you need to use some special API to use the memory and it doesn’t behave like normal system memory. Examples for the second case would be VAAPI and OpenGL, where you have to use special APIs to do something with the memory, or the new DMA-BUF Linux kernel API, where you just pass around a file descriptor that might be mappable to the process’ virtual address space via mmap().

Custom memory types

In 0.10 special memory was usually handled by subclassing GstBuffer, and somehow ensuring that you could get a buffer of the correct type an it’s not copied to a normal GstBuffer in between. It was very unreliable and rather hackish usually.

In 1.0 it’s no longer possible to subclass GstBuffer, and GstBuffer is only a collection of memory abstraction objects and metadata. You would now implement a custom GstMemory and GstAllocator. GstMemory here is just representing an instance or handle to a specific memory but itself has no logic implemented. For the logic it would point to its corresponding GstAllocator. The reason for this split is mainly that a) there might be multiple allocators for a single memory type (think of the different ways of allocating an EGLImage), and b) that you want to negotiate the allocator and memory type between elements before allocating any of these memories.

This new abstraction of memory has explicit operations to request read, write or exclusive access to the memory and for usage like normal system memory requires an explicit call to gst_memory_map(). This mapping to system memory allows to use it from C like memory allocated via malloc(), but might not be possible for every type of memory. Subclasses of GstMemory could have to implement all these operations and map them to whatever this specific type of memory provides, and could provide additional API on top of that. The memory could also be marked as read-only, or could even be inaccessible for the process and just passed around as an opaque handle between elements.

Let me give some examples. For DMA-BUF you would for example implement the mapping to the virtual address space of the process via mmap() (which is done by GstDmabufMemory), for VAAPI you could implement additional API for the memory that could provide the memory as an GL texture id or convert it to a different color format (which is done by gst-vaapi), for memory that represents a GL texture id you could implement mapping to the process’ virtual address space by dispatching an operation to the GL thread and using glTexImage2D() or glReadPixels() and implement copying of memory in a similar way (which is done by gst-plugins-gl). You could also implement some kind of access control for the memory, which would allow easier implementation of DRM schemes (all engineers are probably dying a bit inside while reading this now…), or do crazy things like implementing some kind of file-backed memory.

With GstBuffer just being a collection of memories now, it provides convenience API to handle all the contained memories, e.g. to copy all of them, or map all of them to the process’ virtual address space.

Memory constraints

If all you need is just some memory that behaves like normal, malloc’d memory but fulfils some additional constraints like alignment or being physically contiguous you don’t need to implement your own GstMemory and GstAllocator subclass. The allocation function of GstAllocator, gst_allocator_alloc(), allows to provide parameters to specify such things and the default memory implementations handles this just fine.

For format specific constraints, like having a special rowstride of raw video frames, or having their planes in separate memory regions, something else can be done which I will mention later when talking about arbitrary buffer metadata.

So far I’m not aware of any special type of memory that can’t be handled with the new API, and I think it’s rather unlikely that there ever will be one. In the worst case it will just be a bit inconvenient to write the code.

Buffer pools

In many cases it will be useful to not just allocate a new block of memory whenever one is required, but instead keep track of memory in a pool and recycle memory that is currently unused. For example because allocations are just too expensive or because there is only a very limited number of memory blocks available anyway.

For this GstBufferPool is available. It provides a generic buffer pool class with standard functionality (setting of min/max number of buffers, pre-allocation of buffers, allocation parameters, allow/forbid dynamic allocation of buffers, selection of the GstAllocator, etc) and can be extended by subclasses with custom API and configuration.

As the most common case for buffer pools is for raw video, there’s also a GstVideoBufferPool subclass which already implements a lot of common functionality. For example it cares for allocating memory of the right size and caps handling, allows for configuration of custom rowstrides or using separate memory regions for the different planes and implements a custom configuration interface for specifying additional padding around each plane (GstVideoAlignment).

Arbitrary buffer metadata

In GStreamer 1.0 you can attach GstMeta to a buffer to represent arbitrary metadata, which can be used for all kinds of different things. GstMeta provides generic descriptions about the aspects of a buffer it applies to (tags) and functions to transform the meta (e.g. if a filter changes the aspect the meta applies too). The GstMeta supported by elements can also be negotiated between them to make sure all elements in a chain support a specific kind of metadata if it needs to care about it.

Examples for GstMeta usage would be the additional of simple metadata to buffers. Metadata like defining a rectangle with region of interests on a video frame (e.g. for face detection), or defining the gamma transfer function that applies to a video frame or defining custom rowstrides, or defining special downmix matrixes for converting 5.1 audio to stereo. While these are all examples that mostly apply to raw audio and video, it is also possible to implement metas that describe compressed formats, e.g. a meta that provides an MPEG sequence header as parsed C structures.

Apart from simple metadata it is also possible to use GstMeta for delayed processing, for example if all elements in a chain support a cropping metadata, it would be possible to not crop the video frame in the decoder but instead let the video sink handle the cropping based on a cropping rectangle put on the buffer as metadata. Or subtitles could be put on a buffer as metadata instead of overlaying them on top of the frame, and only in the sink after all other processing the subtitles would be overlaid on top of the video frame.

And then it’s also possible to use GstMeta to define “dynamic interfaces” on buffers. The metadata could for example contain a function pointer to a function that allows to upload the buffer to a GL texture, which could be simply implemented via glTexImage2() for normal memory or via special VAAPI for memory that is backed by VAAPI memory.

All the examples given in the previous paragraphs are already implemented by GStreamer and can just be re-used by other elements and we plan to add more generic GstMeta in the future. Look for GstVideoMeta, GstVideoCropMeta, GstVideoGLTextureUploadMeta, GstVideoOverlayMeta and GstAudioDownmixMeta for example.

Do not use GstMeta for memory specific information, e.g. as a lazy way to get around implementing a custom GstMemory and GstAllocator. It won’t work as optimal!

Negotiation

Compared to 0.10, negotiation between elements was extended by another step. There’s a) caps negotiation and b) allocation negotiation. Each of these happens before data-flow and after receiving a RECONFIGURE event.

caps negotiation

During caps negotiation the pads of the elements decide on one specific format that is supported by both linked pads and also make it possible for further downstream elements to decide on a specific format. Caps in GStreamer represent such a specific format and its properties, and is represented in a mime-type similar way with properties, e.g. “video/x-h264,width=1920,height=1080,profile=main”.

GstCaps can contain a list of such formats, represented as GstStructures, and each of these structures contain a name and a list of fields. The values of the fields can either be concrete, single values or describing multiple values (e.g. by using integer ranges). On top of caps many generic operations are defined to check compatibility of caps, to create intersections, to merge caps or to convert them into a single, fixed format (which is required during negotiation). If multiple structures are contained in a caps, they are ordered by preference.

All this is nothing new, but in GStreamer 1.2 caps were extended by GstCapsFeatures, which allows to add additional constraints to caps. For example a specific memory type can be requested or the existence of specific metadata. This is used during negotiation to make sure only compatible elements are linked (e.g. ones that can only work with EGLImage memory would not be seen as compatible with ones that only can handle VAAPI memory although everything else of the caps is the same), and is also used in autoplugging elements like playbin to select the most optimal decoder and sink combinations. An example of such caps with caps features would be “video/x-raw(memory:EGLImage),width=1920,height=1080″ to specify that EGLImage memory is required.

So, the actual negotiation of the caps happens from upstream to downstream. The most downstream element uses a CAPS query, which replaces the getcaps function of pads from 0.10 and has an additional filter argument in 1.0. The filter argument is used to tell downstream which caps are actually supported by upstream and in which preference, so it don’t have to create unnecessary caps. This query is then propagated further downstream to the next elements, translated if necessary (e.g. from raw video caps to h264 caps by an encoder, while still proxying the values of the width/height fields), then answered by the most downstream element that doesn’t propagate the query further downstream and filled with the caps supported by this element’s pad. On the way back upstream these result caps are further narrowed down, translated between different formats and potentially reordered by preference. Once the results are received in the most upstream element, it tries to choose on specific format from those supported by downstream and itself, while keeping preferences of itself and downstream under consideration. Then as a last step it sends a CAPS event downstream to notify about the actually chosen caps. This CAPS event is then further propagated downstream by elements (if necessary translated) that don’t need further information to decide on their output format, or stored and later when all necessary information is available (e.g. after the header buffers are received and parsed) a new CAPS event is sent downstream with the new caps.

This is all very similar to how the same worked in 0.10.

allocation negotiation

The next step, the allocation negotiation, is something new in 1.0. The ALLOCATION query is used by every most upstream element that needs to allocate buffers (i.e. sources, converters, decoders, encoders, etc) to get information about the allocation possibilities from downstream.

The ALLOCATION query is created with the caps that the upstream element wants first answered by the most downstream element that by itself would allocate new buffers again for its own downstream (i.e. converters, decoders, encoders). It’s filled with any buffer pools that can be provided by downstream, allocators (and thus memory types), the minimum and maximum number of buffers, the allocation size, allocation parameters and the supported metas. On its way back upstream these results are filtered and narrowed down by the further upstream elements (e.g. to remove metas that are not supported by an element, or a memory type), and especially the minimum and maximum number of buffers is updated by each element. The querying element will then decide to use one of the buffer pools and/or allocators and which metas can be used and which not. It can also decide to not use any of the buffer pools or allocators and use its own that is compatible with the results of the query.

The usage of downstream buffer pools or allocators is the 1.0 replacement of gst_pad_alloc_buffer() in 0.10, and its much more efficient as the complete way downstream does not have to be walked for every buffer allocation but only once.

Note: the caps in the ALLOCATION query are not required to be the same as in the CAPS event. For example if the video crop metadata is used, the caps in the CAPS event will contain the cropped width and height while the caps in the ALLOCATION query will contain the uncropped (larger) width and height.

Context sharing

Another problem that often needs to be solved for hardware integration (but also other use cases), is the sharing of some kind of context between elements. Maybe even before these elements are linked together. For example you might need to share a VADisplay or EGLDisplay between your decoder and your sink, or an OpenGL context (plus thread dispatching functionality), or unrelated to hardware integration you might want to share an HTTP session (e.g. cookies) with multiple elements.

In GStreamer 1.2 support for doing this was added to GStreamer core via GstContext.

GstContext allows sharing such a context in a generic way via a name to identify the type of context and a GstStructure to store various information about it. It is distributed in the pipeline the following way: Whenever an element needs a specific context it first checks if one of the correct type was set on it before (for which the GstElement::set_context vfunc would’ve been called). Otherwise it will query downstream and then upstream with the CONTEXT query to retrieve any locally known contexts of the correct type (e.g. a decoder could get a context from a sink). If this doesn’t give any result either, the element is posting a NEED_CONTEXT message on the bus. This is then sent upwards in the bin hierarchy and if one of the containing bins knows a context of the correct type it will synchronously set it on the element. Otherwise the application will get the NEED_CONTEXT message and has the possibility to set a context from a sync bus handler on the element. If the element still has no context set, it can create one itself and advertise it in the bin hierarchy and to the application with the HAVE_CONTEXT message. When receiving this message, bins will cache the contexts and will use them the next time a NEED_CONTEXT message is seen. The same goes for contexts that were set on a bin, those will also be cached by the bin for future use.

All in all this does not require any interaction with the application, unless the application wants to configure which contexts are set on which elements.

To make the distributing of contexts more reliable, decodebin has a new “autoplug-query” signal, which can be used to forward CONTEXT (and ALLOCATION) queries of not-yet-exposed elements during autoplugging to downstream elements (e.g. sinks). This is also used by playbin to make sure elements can reach the sinks during autoplugging.

Open issues

Does this mean that GStreamer is complete now? No There are still some open issues around this, but these should be fixable in 1.x without any problems. All the building blocks are there. Overall hardware integration is already working much much better than in 0.10.

Reconfiguration

One remaining issue is the handling of device reconfiguration. Often it is required to release all memory allocated from a device before being able to set a new configuration on the device and allocate new memory. The problem with this is that GStreamer elements currently have no control about downstream or upstream elements that use their memory, there is no API to request them to release memory. And even if there was it would be a bit tricky to integrate into 3rd party libraries like libav, as they keep references to memory internally for things like reference frames.

Related to this is that currently buffer pools only keep track of buffers, but there’s nothing that makes it easy to keep track of memories. Implementing this over and over again in GstAllocator subclasses is error-prone and inconvenient.

All discussions about this and some initial ideas are currently handling in Bugzilla #707534

Device probing

The other remaining issue is missing API for device probing, e.g. to get all available camera devices together with the GStreamer elements that can be used to access them. In 0.10 there was a very suboptimal solution for this, and it was removed for 1.0 without any replacement so far.

There is a patch with a new implementation of this in Bugzilla #678402. The new idea now is to implement a custom GstPluginFeature, that allows creating devices probing instances for elements from the registry (similar to GstElementFactory). This is planned to be integrated really soon now and should be in 1.4.

Summary

In practise this currently means that it’s possible to use gst-vaapi transparently in playbin, without the application having to know about anything VAAPI related. playbin will automatically select correct decoders and sinks and have them use in an optimal way together. This even works inside a WebKit HTML5 website together with fancy CSS3 effects.

gst-omx and the v4l2 plugin can now provide zerocopy operation, a slow ARM based device like the Raspberry Pi can decode HD video in realtime to EGLImages and display them, gst-plugins-gl has a solution to all OpenGL related threading problems, and many many more.

I think with what we have in GStreamer 1.2 we should be able to integrate all kinds of hardware in an optimal way and have it used transparently in pipelines. Some APIs might be missing, but there should be nothing that can’t be added rather easily now.

While doing work on UPower, trying to reduce its wake-ups when idle, I realised that a couple of applications on my desktop were waking up far more than should be necessary.

Detecting wake-ups

First, we need to detect wake-ups. This is a fairly well-known, and old, process, using the venerable PowerTop.

# powertop --html=/tmp/foo.html --time=60

You can increase the number of seconds to get a more realistic view of your machine's idleness, but this is enough to show the main culprits.

In my case, evolution, gnote and devhelp were all waking up about 30 times a second whilst mostly idle. Evolution might be an outlier, as it also talks to the network, and is a bigger application to debug, so I started with devhelp.

$ strace -vvv -p `pidof devhelp`
Process 19069 attached
restart_syscall(<... resuming interrupted call ...>) = 0
recvfrom(6, 0x23fece4, 4096, 0, 0, 0)   = -1 EAGAIN (Resource temporarily unavailable)
poll([{fd=5, events=POLLIN}, {fd=6, events=POLLIN}, {fd=3, events=POLLIN}], 3, 17) = 0 (Timeout)
recvfrom(6, 0x23fece4, 4096, 0, 0, 0)   = -1 EAGAIN (Resource temporarily unavailable)
poll([{fd=5, events=POLLIN}, {fd=6, events=POLLIN}, {fd=3, events=POLLIN}], 3, 17) = 0 (Timeout)

Overview

Rockwatch allows your N9 to communicate with a Pebble smart watch. It makes it possible to install and manage Pebble apps, upgrade your Pebble’s firmware, receive notifications of e-mails and SMS messages and control your music from your Pebble.

New features in version 1.1

• Preliminary support for the HTTPebble protocol which allows watch faces and apps to communicate with HTTP servers via the phone’s network connection and also provides them with location information. For example this provides support for watch faces that display local weather information, like Fair Forecast.
• The ability to set the watch’s time from the N9′s clock.

Upcoming features

In the next version I hope to add support for accessing the two-way SDK via DBUS, this will allow other N9 applications to communicate with watch apps and get feedback from the watch.

Download

Available in the Ovi Store

As is becoming common, we will have some more power management changes in GNOME 3.12, though those changes will also affect other desktops, whether they use UPower's D-Bus interface, or libupower-glib, the helper library.

The goals of the exercise were simple:

• reduce wake-ups on the daemon and on the client side
• reduce code duplication amongst desktop environments, and even within the same environment (composite battery, anyone?)
• moving some policy actions to a lower level (one could not request hibernation or suspend when multiple users were logged in without interaction and passwords)

All those changes are now in UPower master ready for testing.

Out with the old

The deprecated interfaces for Suspend, Hibernate, etc. are finally removed, after being obsoleted by logind. We've also removed the QoS interface that nobody was using, and the out-dated battery recall support. It's not that batteries don't explode any more, it's that they don't all come from known-bad batches.

In with the new

We have 2 new properties on each of the devices.

WarningLevel which uses daemon-side configurations to tell you whether a device's battery level is low, critically low, or whether we're about to take action on that critical level.

We also have IconName, which replaces some cut'n'pasted code between desktop components. If your desktop environment has many more icons for all types of devices on low battery, for example, you can ignore this property and use the code you always have.

Using those new properties usefully is the new DisplayDevice object. It groups all the batteries and UPSes in the daemon into one, easy to use object that you can use to display a single status icon in your shell chrome. Obviously, if you want to show more devices, the individual batteries and UPSes are still available through the usual means. And it obviously has the 2 new properties mentioned above, so your session daemon can get told when to show notifications for low batteries.

And finally, using that new combined DisplayDevice is the critical battery action policies. As mentioned above, multi-user systems could not hibernate without requiring the user to enter an administrator password, which is less than convenient when your machine is running out of UPS power fast. The configuration for that policy is now in the daemon itself, with sane defaults, and it will hibernate the machine for you.

And to the modernisation

libupower-glib now uses GDBus, even if the daemon doesn't. The daemon however sends PropertiesChanged signals which means that modern D-Bus bindings will automatically get the new values for properties, instead of polling the daemon. The DeviceChanged and Changed signals have thus been removed.

API changes

They are numerous, too many to mention here. I've posted to the device-kit mailing-list with a list of changes that were made, reply there if you have any questions regarding using UPower in your application or session daemons.

Miscellaneous

systemd >= 207 will save your brightness settings across reboots, and the upcoming systemd 209 will have support for saving keyboard backlight across reboots.

I've made attempts at supporting Intel Rapid Start in systemd, but this will actually require kernel changes. Hopefully we should be able to land this by the time GNOME 3.12 is released.

Overview

Rockwatch allows your N9 to communicate with a Pebble smart watch. It makes it possible to install and manage Pebble apps, upgrade your Pebble’s firmware, receive notifications of e-mails and SMS messages and control your music from your Pebble.

Upcoming features

The next release will add:

• Preliminary support for the HTTPebble protocol which allows watch faces and apps to communicate with HTTP servers via the phone’s network connection and also provides them with location information. For example this provides support for watch faces that display local weather information, like Fair Forecast.
• The ability to set the watch’s time from the N9′s clock.

Videos

Video showing music control

Video showing installation of apps

Video showing notifications

Download

Available in the Ovi Store

Hi world! It’s been several years since I used this blog, and there’s been a lot of things happen to us since then. I don’t even live on the same continent as I did.

More on that in a future post. Today, I have an announcement to make – a new Open Source company! Together with fellow GStreamer hackers Tim-Philipp Müller and Sebastian Dröge, I have founded a new company: Centricular Ltd.

From 2007 until July, I was working at Oracle on Sun Ray thin client firmware. Oracle shut down the project in July, and my job along with it – opening up this excellent opportunity to try something I’ve wanted for a while and start a business, while getting back to Free Software full time.

Our website has more information about the Open Source technologies and services we plan to offer. This list is not complete and we will try to broaden it over time, so if you have anything interesting that is not listed there but you think we can help with, get in touch

As Centricular’s first official contribution to the software pool, here’s my Raspberry Pi Camera GStreamer module. It wraps code from Raspivid to allow direct capture from the official camera module and hardware encoding to H.264 in a GStreamer pipeline – without the shell pipe and fdsrc hack people have been using to date. Take a look at the README for more information.

Sebastian, Tim and I will be at the GStreamer Conference in Edinburgh next week.

I have a new job! After working for 5+ years for Collabora, I decided that it’s time for a change and have quit my contract there early September. These have been great years, working with so many brilliant people on Free Software, but time to move on!

So for the future, it’s actually more than just a new job. Together with fellow GStreamer hackers Tim-Philipp Müller and Jan Schmidt we founded a new company: Centricular Ltd.. We are going to provide consultancy services around Free Software with a focus on GStreamer, Multimedia and Graphics initially (but not exclusively). Technically, not much will change in the kind of work I’m doing compared to the past, but this time we will handle everything ourselves so we can better serve the needs of our customers and are more flexible. Hopefully this also provides an even better work environment within a group of equals and gives us more time to contribute to GStreamer and other Free Software projects.

Check our website for a list of Open Source technologies we cover and services we will offer. Obviously this list is not complete and we will try to broaden it over time, so if you have anything interesting that is not listed there but you would need someone for, just ask.

We will also be at the GStreamer Conference in Edinburgh next week.

Great times ahead!

We sometimes grumble a bit about Google in the community when they do things we feel are not generally helpful to the overall community. But I think we should be equally good at saying thanks when Google do great things. So thanks to our LibreOffice superstar Caolán McNamara I was made aware that Google has released two new open fonts along with Chrome. So what is so exciting about a new font you say?

Well one of them, called Carlito, is metrically compatible with the current MS default font called Calibri. You can get the font here. It is licensed under the OFL 1.1.

So for those wondering what metrically compatible means, I for sure did when I first heard the term, it basically mean that while the individual glyphs in the font doesn’t look like the Calibri font (that would not be legal), each individual letter has the same height and width as their Calibri counterpart. This means that if you import a document using Calibri into LibreOffice and you don’t have Calibri or a metrically compatible font installed, your document layout would change as the font LibreOffice would need to use instead have letters that might in general be slightly wider for instance. So with Carlito installed this will no longer be a problem, the glyphs might look a bit different, but you can be sure that the overall layout stays the same.

And for certain professions that can be crucial, for instance try speaking to the legal team of your company about them using LibreOffice and they are likely to tell you that they will only do that if they can feel certain that when another lawyer sends them a contract, the layout will not change when they view it, as such changes could at least potentially be the cause of a dispute over the meaning of a paragraph. (That worry was probably the main reason the legal profession stayed with Word Perfect for such a long time, when the rest of the world had moved on.)

So we are now going to get this new font packaged for Fedora and Red Hat Enterprise Linux so soon as possible, to make your productivity experience even better

So thank you Google, this is much appreciated!

And so it has come to this.

A few days ago, we stealthily published the tarball of the first Pitivi video editor release based on the GES engine. Incredible but true! 0.91 is finally out! In case you were living under a rock for the past two years, this release is the result of a major rework of the entire Pitivi architecture, and as such it is considered an “alpha” release. From a very (VERY) high level, it includes:

• Replacing the core of Pitivi by GES; 20 thousand lines of code removed
• Porting to GStreamer 1.x
• Porting to GTK+ 3.x
• Replacing GooCanvas by Clutter for the timeline
• An automated UI test suite, with many checks for mission-critical parts
• Fixing hundreds of bugs
• Implementing many new features
• UI polish all over the place
• Refactoring pretty much the entire codebase

Since 0.15.2, over 1300 changes have been committed in Pitivi alone. That’s not even counting the incredible amount of work we’ve done in GES and GStreamer. See the details in the 0.91 release notes.

I would like to extend my deepest thanks to all the people who, through their contributions and the trust they have put in us over the past two years, have helped us achieve this milestone. The adventure continues however: we need your involvement more than ever to continue on the path we have set! If you’ve been shy about getting involved because of the huge amount of architectural changes we were going through, now is the perfect time to start contributing on fresh grounds.

Oh, and one more thing: “PiTiVi” is now known as “Pitivi”. Our website, documentation and infrastructure have been updated to reflect this small branding adjustment (the only part I didn’t update yet is the logo image). Moreover, in order to support open standards, free ourselves from YouTube (or any third party, really) and to make it easier to transition to a responsive design (more on that later), we now use HTML5 videos in open formats all across the website. Woohoo!

In the past many people joined the GStreamer IRC channel on FreeNode and were asking how to stream a GStreamer pipeline to multiple clients via HTTP. Just explaining how to do it and that it’s actually quite easy might not be that convincing, so here’s a small tool that does exactly that. I called it http-launch and you can get it from GitHub here.

Given a GStreamer pipeline in GstParse syntax (same as e.g. gst-launch), it will start an HTTP server on port 8080, will start the pipeline once the first client connects and then serves from a single pipeline all following clients with the data that it produces.

For example you could call it like this to stream a WebM stream:

http-launch webmmux streamable=true name=stream videotestsrc ! vp8enc ! stream. audiotestsrc ! vorbisenc ! stream.


Note that this is just a simple example of what you can do with GStreamer and not meant for production use. Something like gst-streaming-server would be better suited for that, especially once it gets support for HLS/DASH or similar protocols.

Now let’s walk through the most important parts of the code.

The HTTP server

First some short words about the HTTP server part. Instead of just using libsoup, I implemented a trivial HTTP server with GIO. Probably not 100% standards compliant or bug-free, but good enough for demonstration purposes . Also this should be a good example of how the different network classes of GIO go together.

The HTTP server is based on a GSocketService, which listens on a specific port for new connections via a GLib main context, and notifies via a signal whenever there is a new connection. These new connections are provided as a GSocketConnection. These are line 424 and following, and line 240 and following.

In lines 240 and following we start polling the GIOStream of the connection, to be notified whenever new data can be read from the stream. Based on this non-blocking reading from the connection is implemented in line 188 and following. Something like this pattern for non-blocking reading/writing to a socket is also implemented in GStreamer’s GstRTSPConnection.

Here we trivially read data until a complete HTTP message is received (i.e. “\r\n\r\n” is detected in what we read), which is then parsed with the GLib string functions. Only GET and HEAD requests are handled in very simple ways. The GET request will then lead us to the code that connects this HTTP server with GStreamer.

Really, consider using libsoup if you want to implement an HTTP server or client!

The GStreamer pipeline

Now to the GStreamer part of this small application. The actual pipeline is, as explained above, passed via the commandline. This is then parsed and properly set up in line 362 and following. For this GstParse is used, which parses a pipeline string into a real GstBin.

As the pipeline string passed to http-launch must not contain a sink element but end in an element with the name “stream”, we’ll have to get this element now and add our own sink to the bin. We do this by getting the “stream” element via gst_bin_get_by_name(), setting up a GstGhostPad that proxies the source pad of it as a source pad of the bin, and then putting the bin created from the pipeline string and a sink element into a GstPipeline, where both (the bin and the sink) are then connected.

The sink we are using here is multisocketsink, which sends all data received to a set of aplication-provided GSockets. In line 390 and following we set up some properties on the sink that makes sure that newly connected clients start from a keyframe and that the buffering for all clients inside multisocketsink is handled in a sensible way. Instead of letting new clients wait for the next keyframe we could also explicitly request the pipeline to generate a new keyframe each time a client connects.

Now the last part missing is that whenever we successfully received a GET request from a client, we will stop handling any reads/writes from the socket ourselves and pass it to multisocketsink. This is done in line 146. From this point onwards the socket for this client is only handled by multisocketsink. Additionally we start the pipeline here for the first client that has successfully connected.

I hope this showed a bit how one of the lesser known GStreamer elements can be used to stream media to multiple clients, and that GStreamer provides building blocks for almost everything already

This blog post might be a bit late but nonetheless, here are some updates that happened in GStreamer in the last week

GStreamer 1.2.0 released

On Tuesday we released GStreamer 1.2.0. This was just in time for GNOME 3.10, which depends on it and was released on Wednesday (Congrats btw! Many great improvements).

The changes between GStreamer 1.0 and 1.2 can be seen from the release announcement mail. In summary there are many, many nice new features, API improvements and even more bugfixes that we did not include in the 1.0.x bugfix releases because they required larger changes.

Following the 1.2.0 release we plan to do regular 1.2.x bugfix releases with important bugfixes, while at the same time develop new features and in general more complicated changes in the already opened 1.3 development release series (which is the GIT master branch now). The 1.3 release series will later lead to the next stable 1.4 release series. Needless to say that 1.4 will be completely backwards-compatible with 1.2 and 1.0.

GStreamer 1.2.0 binaries

Two days later on Thursday we then released the binaries for GStreamer 1.2.0 for Android (ARM), Mac OS X and Windows. This will allow to take advantage of all the new changes on these platforms too and provide a better cross-platform multimedia experience.

We also finally moved cerbero, the build system used to generate the binaries for all these platforms, to GStreamer’s freedesktop.org GIT and got rid of all the ancient 0.10 cruft that was still in there. This GIT repository is now the official place from where you can get the latest version of cerbero for building GStreamer, and will also be updated for all future 1.2.x bugfix releases. Hopefully it will also be kept up-to-date for GIT master, i.e. the 1.3 development release series.

iOS binaries and build support

Over the last days I also worked on porting the remaining parts of GStreamer 1.0 to iOS (5.1 and newer versions), and also adapted the cerbero build system to automatically build GStreamer 1.0 for iOS and create an installer package from it. iOS binaries were already available in the past from a third-party website (gstreamer.com) but only for the old and deprecated 0.10 version. My changes are based on this.

It’s now also possible to build GStreamer and all its dependencies via cerbero with the Xcode 5.0 toolchain for OS X and iOS. Thanks to more strict compiler checks and behaviour changes, some changes in the build systems and the code were necessary.

Official binaries for iOS will be provided by the GStreamer project in the next days.

Others

gstreamer-vaapi was already ported to the new 1.2 API for better hardware integration and the next release should contain it. Finally it can do all that without using unstable GStreamer API.

Also gnonlin, gst-editing-services and gst-python finally saw a 1.x based (pre-) release. The final 1.2.0 releases should be there in the next days, and hopefully a new PiTiVi release will follow soonish.

GStreamer conference 2013

In October the GStreamer Conference 2013 will happen in Edinburgh. There will be many interesting talks by the GStreamer developers but also other people and companies, who will give talks about what they achieved with GStreamer.

I’ll give a talk about how to integrate hardware capabilities into GStreamer, and which new APIs were added to make this much easier or possible at all (depending on what kind of integration is needed).