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kernel / Documentation / userspace-api / media / mediactl / request-api.rst
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  1.. SPDX-License-Identifier: GPL-2.0 OR GFDL-1.1-no-invariants-or-later
  2.. c:namespace:: MC
  3
  4.. _media-request-api:
  5
  6Request API
  7===========
  8
  9The Request API has been designed to allow V4L2 to deal with requirements of
 10modern devices (stateless codecs, complex camera pipelines, ...) and APIs
 11(Android Codec v2). One such requirement is the ability for devices belonging to
 12the same pipeline to reconfigure and collaborate closely on a per-frame basis.
 13Another is support of stateless codecs, which require controls to be applied
 14to specific frames (aka 'per-frame controls') in order to be used efficiently.
 15
 16While the initial use-case was V4L2, it can be extended to other subsystems
 17as well, as long as they use the media controller.
 18
 19Supporting these features without the Request API is not always possible and if
 20it is, it is terribly inefficient: user-space would have to flush all activity
 21on the media pipeline, reconfigure it for the next frame, queue the buffers to
 22be processed with that configuration, and wait until they are all available for
 23dequeuing before considering the next frame. This defeats the purpose of having
 24buffer queues since in practice only one buffer would be queued at a time.
 25
 26The Request API allows a specific configuration of the pipeline (media
 27controller topology + configuration for each media entity) to be associated with
 28specific buffers. This allows user-space to schedule several tasks ("requests")
 29with different configurations in advance, knowing that the configuration will be
 30applied when needed to get the expected result. Configuration values at the time
 31of request completion are also available for reading.
 32
 33General Usage
 34-------------
 35
 36The Request API extends the Media Controller API and cooperates with
 37subsystem-specific APIs to support request usage. At the Media Controller
 38level, requests are allocated from the supporting Media Controller device
 39node. Their life cycle is then managed through the request file descriptors in
 40an opaque way. Configuration data, buffer handles and processing results
 41stored in requests are accessed through subsystem-specific APIs extended for
 42request support, such as V4L2 APIs that take an explicit ``request_fd``
 43parameter.
 44
 45Request Allocation
 46------------------
 47
 48User-space allocates requests using :ref:`MEDIA_IOC_REQUEST_ALLOC`
 49for the media device node. This returns a file descriptor representing the
 50request. Typically, several such requests will be allocated.
 51
 52Request Preparation
 53-------------------
 54
 55Standard V4L2 ioctls can then receive a request file descriptor to express the
 56fact that the ioctl is part of said request, and is not to be applied
 57immediately. See :ref:`MEDIA_IOC_REQUEST_ALLOC` for a list of ioctls that
 58support this. Configurations set with a ``request_fd`` parameter are stored
 59instead of being immediately applied, and buffers queued to a request do not
 60enter the regular buffer queue until the request itself is queued.
 61
 62Request Submission
 63------------------
 64
 65Once the configuration and buffers of the request are specified, it can be
 66queued by calling :ref:`MEDIA_REQUEST_IOC_QUEUE` on the request file descriptor.
 67A request must contain at least one buffer, otherwise ``ENOENT`` is returned.
 68A queued request cannot be modified anymore.
 69
 70.. caution::
 71   For :ref:`memory-to-memory devices <mem2mem>` you can use requests only for
 72   output buffers, not for capture buffers. Attempting to add a capture buffer
 73   to a request will result in an ``EBADR`` error.
 74
 75If the request contains configurations for multiple entities, individual drivers
 76may synchronize so the requested pipeline's topology is applied before the
 77buffers are processed. Media controller drivers do a best effort implementation
 78since perfect atomicity may not be possible due to hardware limitations.
 79
 80.. caution::
 81
 82   It is not allowed to mix queuing requests with directly queuing buffers:
 83   whichever method is used first locks this in place until
 84   :ref:`VIDIOC_STREAMOFF <VIDIOC_STREAMON>` is called or the device is
 85   :ref:`closed <func-close>`. Attempts to directly queue a buffer when earlier
 86   a buffer was queued via a request or vice versa will result in an ``EBUSY``
 87   error.
 88
 89Controls can still be set without a request and are applied immediately,
 90regardless of whether a request is in use or not.
 91
 92.. caution::
 93
 94   Setting the same control through a request and also directly can lead to
 95   undefined behavior!
 96
 97User-space can :c:func:`poll()` a request file descriptor in
 98order to wait until the request completes. A request is considered complete
 99once all its associated buffers are available for dequeuing and all the
100associated controls have been updated with the values at the time of completion.
101Note that user-space does not need to wait for the request to complete to
102dequeue its buffers: buffers that are available halfway through a request can
103be dequeued independently of the request's state.
104
105A completed request contains the state of the device after the request was
106executed. User-space can query that state by calling
107:ref:`ioctl VIDIOC_G_EXT_CTRLS <VIDIOC_G_EXT_CTRLS>` with the request file
108descriptor. Calling :ref:`ioctl VIDIOC_G_EXT_CTRLS <VIDIOC_G_EXT_CTRLS>` for a
109request that has been queued but not yet completed will return ``EBUSY``
110since the control values might be changed at any time by the driver while the
111request is in flight.
112
113.. _media-request-life-time:
114
115Recycling and Destruction
116-------------------------
117
118Finally, a completed request can either be discarded or be reused. Calling
119:c:func:`close()` on a request file descriptor will make
120that file descriptor unusable and the request will be freed once it is no
121longer in use by the kernel. That is, if the request is queued and then the
122file descriptor is closed, then it won't be freed until the driver completed
123the request.
124
125The :ref:`MEDIA_REQUEST_IOC_REINIT` will clear a request's state and make it
126available again. No state is retained by this operation: the request is as
127if it had just been allocated.
128
129Example for a Codec Device
130--------------------------
131
132For use-cases such as :ref:`codecs <mem2mem>`, the request API can be used
133to associate specific controls to
134be applied by the driver for the OUTPUT buffer, allowing user-space
135to queue many such buffers in advance. It can also take advantage of requests'
136ability to capture the state of controls when the request completes to read back
137information that may be subject to change.
138
139Put into code, after obtaining a request, user-space can assign controls and one
140OUTPUT buffer to it:
141
142.. code-block:: c
143
144	struct v4l2_buffer buf;
145	struct v4l2_ext_controls ctrls;
146	int req_fd;
147	...
148	if (ioctl(media_fd, MEDIA_IOC_REQUEST_ALLOC, &req_fd))
149		return errno;
150	...
151	ctrls.which = V4L2_CTRL_WHICH_REQUEST_VAL;
152	ctrls.request_fd = req_fd;
153	if (ioctl(codec_fd, VIDIOC_S_EXT_CTRLS, &ctrls))
154		return errno;
155	...
156	buf.type = V4L2_BUF_TYPE_VIDEO_OUTPUT;
157	buf.flags |= V4L2_BUF_FLAG_REQUEST_FD;
158	buf.request_fd = req_fd;
159	if (ioctl(codec_fd, VIDIOC_QBUF, &buf))
160		return errno;
161
162Note that it is not allowed to use the Request API for CAPTURE buffers
163since there are no per-frame settings to report there.
164
165Once the request is fully prepared, it can be queued to the driver:
166
167.. code-block:: c
168
169	if (ioctl(req_fd, MEDIA_REQUEST_IOC_QUEUE))
170		return errno;
171
172User-space can then either wait for the request to complete by calling poll() on
173its file descriptor, or start dequeuing CAPTURE buffers. Most likely, it will
174want to get CAPTURE buffers as soon as possible and this can be done using a
175regular :ref:`VIDIOC_DQBUF <VIDIOC_QBUF>`:
176
177.. code-block:: c
178
179	struct v4l2_buffer buf;
180
181	memset(&buf, 0, sizeof(buf));
182	buf.type = V4L2_BUF_TYPE_VIDEO_CAPTURE;
183	if (ioctl(codec_fd, VIDIOC_DQBUF, &buf))
184		return errno;
185
186Note that this example assumes for simplicity that for every OUTPUT buffer
187there will be one CAPTURE buffer, but this does not have to be the case.
188
189We can then, after ensuring that the request is completed via polling the
190request file descriptor, query control values at the time of its completion via
191a call to :ref:`VIDIOC_G_EXT_CTRLS <VIDIOC_G_EXT_CTRLS>`.
192This is particularly useful for volatile controls for which we want to
193query values as soon as the capture buffer is produced.
194
195.. code-block:: c
196
197	struct pollfd pfd = { .events = POLLPRI, .fd = req_fd };
198	poll(&pfd, 1, -1);
199	...
200	ctrls.which = V4L2_CTRL_WHICH_REQUEST_VAL;
201	ctrls.request_fd = req_fd;
202	if (ioctl(codec_fd, VIDIOC_G_EXT_CTRLS, &ctrls))
203		return errno;
204
205Once we don't need the request anymore, we can either recycle it for reuse with
206:ref:`MEDIA_REQUEST_IOC_REINIT`...
207
208.. code-block:: c
209
210	if (ioctl(req_fd, MEDIA_REQUEST_IOC_REINIT))
211		return errno;
212
213... or close its file descriptor to completely dispose of it.
214
215.. code-block:: c
216
217	close(req_fd);
218
219Example for a Simple Capture Device
220-----------------------------------
221
222With a simple capture device, requests can be used to specify controls to apply
223for a given CAPTURE buffer.
224
225.. code-block:: c
226
227	struct v4l2_buffer buf;
228	struct v4l2_ext_controls ctrls;
229	int req_fd;
230	...
231	if (ioctl(media_fd, MEDIA_IOC_REQUEST_ALLOC, &req_fd))
232		return errno;
233	...
234	ctrls.which = V4L2_CTRL_WHICH_REQUEST_VAL;
235	ctrls.request_fd = req_fd;
236	if (ioctl(camera_fd, VIDIOC_S_EXT_CTRLS, &ctrls))
237		return errno;
238	...
239	buf.type = V4L2_BUF_TYPE_VIDEO_CAPTURE;
240	buf.flags |= V4L2_BUF_FLAG_REQUEST_FD;
241	buf.request_fd = req_fd;
242	if (ioctl(camera_fd, VIDIOC_QBUF, &buf))
243		return errno;
244
245Once the request is fully prepared, it can be queued to the driver:
246
247.. code-block:: c
248
249	if (ioctl(req_fd, MEDIA_REQUEST_IOC_QUEUE))
250		return errno;
251
252User-space can then dequeue buffers, wait for the request completion, query
253controls and recycle the request as in the M2M example above.