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186 lines
8.5 KiB
Markdown
186 lines
8.5 KiB
Markdown
# Playback tutorial 8: Hardware-accelerated video decoding
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### Goal
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Hardware-accelerated video decoding has rapidly become a necessity, as
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low-power devices grow more common. This tutorial (more of a lecture,
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actually) gives some background on hardware acceleration and explains
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how does GStreamer benefit from it.
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Sneak peek: if properly setup, you do not need to do anything special to
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activate hardware acceleration; GStreamer automatically takes advantage
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of it.
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### Introduction
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Video decoding can be an extremely CPU-intensive task, especially for
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higher resolutions like 1080p HDTV. Fortunately, modern graphics cards,
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equipped with programmable GPUs, are able to take care of this job,
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allowing the CPU to concentrate on other duties. Having dedicated
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hardware becomes essential for low-power CPUs which are simply incapable
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of decoding such media fast enough.
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In the current state of things (June 2016) each GPU manufacturer offers
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a different method to access their hardware (a different API), and a
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strong industry standard has not emerged yet.
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As of June 2016, there exist at least 8 different video decoding
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acceleration APIs:
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- [VAAPI](http://en.wikipedia.org/wiki/Video_Acceleration_API) (*Video
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Acceleration API*): Initially designed by
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[Intel](http://en.wikipedia.org/wiki/Intel) in 2007, targeted at the X
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Window System on Unix-based operating systems, now open-source. It now also
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supports Wayland through dmabuf. It is
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currently not limited to Intel GPUs as other manufacturers are free to
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use this API, for example, [Imagination
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Technologies](http://en.wikipedia.org/wiki/Imagination_Technologies) or
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[S3 Graphics](http://en.wikipedia.org/wiki/S3_Graphics). Accessible to
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GStreamer through the [gstreamer-vaapi](https://cgit.freedesktop.org/gstreamer/gstreamer-vaapi/) package.
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- [VDPAU](http://en.wikipedia.org/wiki/VDPAU) (*Video Decode and
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Presentation API for UNIX*): Initially designed by
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[NVidia](http://en.wikipedia.org/wiki/NVidia) in 2008, targeted at the X
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Window System on Unix-based operating systems, now open-source. Although
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it is also an open-source library, no manufacturer other than NVidia is
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using it yet. Accessible to GStreamer through
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the [vdpau](http://cgit.freedesktop.org/gstreamer/gst-plugins-bad/tree/sys/vdpau) element in plugins-bad.
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- [OpenMAX](http://en.wikipedia.org/wiki/OpenMAX) (*Open Media
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Acceleration*): Managed by the non-profit technology consortium [Khronos
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Group](http://en.wikipedia.org/wiki/Khronos_Group "Khronos Group"),
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it is a "royalty-free, cross-platform set of C-language programming
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interfaces that provides abstractions for routines especially useful for
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audio, video, and still images". Accessible to GStreamer through
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the [gst-omx](http://git.freedesktop.org/gstreamer/gst-omx) plugin.
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- [OVD](http://developer.amd.com/sdks/AMDAPPSDK/assets/OpenVideo_Decode_API.PDF)
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(*Open Video Decode*): Another API from [AMD
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Graphics](http://en.wikipedia.org/wiki/AMD_Graphics), designed to be a
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platform agnostic method for softrware developers to leverage the
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[Universal Video
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Decode](http://en.wikipedia.org/wiki/Unified_Video_Decoder) (UVD)
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hardware inside AMD Radeon graphics cards. Currently unavailable to
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GStreamer .
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- [DCE](http://en.wikipedia.org/wiki/Distributed_Codec_Engine)
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(*Distributed Codec Engine*): An open source software library ("libdce")
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and API specification by [Texas
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Instruments](http://en.wikipedia.org/wiki/Texas_Instruments), targeted
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at Linux systems and ARM platforms. Accessible to GStreamer through
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the [gstreamer-ducati](https://github.com/robclark/gst-ducati) plugin.
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- [Android
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MediaCodec](https://developer.android.com/reference/android/media/MediaCodec.html): This is Android's API to access the device's
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hardware decoder and encoder if available. This is accessible through the
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`androidmedia` plugin in gst-plugins-bad. This includes both encoding and
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decoding.
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- Apple VideoTool Box Framework: Apple's API to access h is available
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through the `applemedia` plugin which includes both encoding through
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the `vtenc` element and decoding through the `vtdec` element.
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- Video4Linux: Recent Linux kernels have a kernel API to expose
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hardware codecs in a standard way, this is now supported by the
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`v4l2` plugin in `gst-plugins-good`. This can support both decoding
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and encoding depending on the platform.
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### Inner workings of hardware-accelerated video decoding plugins
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These APIs generally offer a number of functionalities, like video
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decoding, post-processing, or presentation of the decoded
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frames. Correspondingly, plugins generally offer a different GStreamer
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element for each of these functions, so pipelines can be built to
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accommodate any need.
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For example, the `gstreamer-vaapi` plugin offers the `vaapidecode`,
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`vaapipostproc` and `vaapisink` elements that allow
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hardware-accelerated decoding through VAAPI, upload of raw video frames
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to GPU memory, download of GPU frames to system memory and presentation
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of GPU frames, respectively.
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It is important to distinguish between conventional GStreamer frames,
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which reside in system memory, and frames generated by
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hardware-accelerated APIs. The latter reside in GPU memory and cannot
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be touched by GStreamer. They can usually be downloaded to system
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memory and treated as conventional GStreamer frames when they are
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mapped, but it is far more efficient to leave them in the GPU and
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display them from there.
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GStreamer needs to keep track of where these “hardware buffers” are
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though, so conventional buffers still travel from element to
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element. They look like regular buffers, but mapping their content is
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much slower as it has to be retrieved from the special memory used by
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hardware accelerated elements. This special memory types are
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negotiated using the allocation query mechanism.
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This all means that, if a particular hardware acceleration API is
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present in the system, and the corresponding GStreamer plugin is also
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available, auto-plugging elements like `playbin` are free to use
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hardware acceleration to build their pipelines; the application does not
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need to do anything special to enable it. Almost:
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When `playbin` has to choose among different equally valid elements,
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like conventional software decoding (through `vp8dec`, for example) or
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hardware accelerated decoding (through `vaapidecode`, for example), it
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uses their *rank* to decide. The rank is a property of each element that
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indicates its priority; `playbin` will simply select the element that
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is able to build a complete pipeline and has the highest rank.
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So, whether `playbin` will use hardware acceleration or not will depend
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on the relative ranks of all elements capable of dealing with that media
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type. Therefore, the easiest way to make sure hardware acceleration is
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enabled or disabled is by changing the rank of the associated element,
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as shown in this code:
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``` c
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static void enable_factory (const gchar *name, gboolean enable) {
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GstRegistry *registry = NULL;
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GstElementFactory *factory = NULL;
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registry = gst_registry_get_default ();
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if (!registry) return;
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factory = gst_element_factory_find (name);
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if (!factory) return;
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if (enable) {
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gst_plugin_feature_set_rank (GST_PLUGIN_FEATURE (factory), GST_RANK_PRIMARY + 1);
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}
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else {
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gst_plugin_feature_set_rank (GST_PLUGIN_FEATURE (factory), GST_RANK_NONE);
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}
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gst_registry_add_feature (registry, GST_PLUGIN_FEATURE (factory));
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return;
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}
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```
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The first parameter passed to this method is the name of the element to
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modify, for example, `vaapidecode` or `fluvadec`.
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The key method is `gst_plugin_feature_set_rank()`, which will set the
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rank of the requested element factory to the desired level. For
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convenience, ranks are divided in NONE, MARGINAL, SECONDARY and PRIMARY,
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but any number will do. When enabling an element, we set it to
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PRIMARY+1, so it has a higher rank than the rest of elements which
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commonly have PRIMARY rank. Setting an element’s rank to NONE will make
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the auto-plugging mechanism to never select it.
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> ![warning] The GStreamer developers often rank hardware decoders lower than
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> the software ones when they are defective. This should act as a warning.
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## Conclusion
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This tutorial has shown a bit how GStreamer internally manages hardware
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accelerated video decoding. Particularly,
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- Applications do not need to do anything special to enable hardware
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acceleration if a suitable API and the corresponding GStreamer
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plugin are available.
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- Hardware acceleration can be enabled or disabled by changing the
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rank of the decoding element with `gst_plugin_feature_set_rank()`.
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It has been a pleasure having you here, and see you soon!
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[warning]: images/icons/emoticons/warning.png
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