1.. SPDX-License-Identifier: GFDL-1.1-no-invariants-or-later 2 3.. _subdev: 4 5******************** 6Sub-device Interface 7******************** 8 9The complex nature of V4L2 devices, where hardware is often made of 10several integrated circuits that need to interact with each other in a 11controlled way, leads to complex V4L2 drivers. The drivers usually 12reflect the hardware model in software, and model the different hardware 13components as software blocks called sub-devices. 14 15V4L2 sub-devices are usually kernel-only objects. If the V4L2 driver 16implements the media device API, they will automatically inherit from 17media entities. Applications will be able to enumerate the sub-devices 18and discover the hardware topology using the media entities, pads and 19links enumeration API. 20 21In addition to make sub-devices discoverable, drivers can also choose to 22make them directly configurable by applications. When both the 23sub-device driver and the V4L2 device driver support this, sub-devices 24will feature a character device node on which ioctls can be called to 25 26- query, read and write sub-devices controls 27 28- subscribe and unsubscribe to events and retrieve them 29 30- negotiate image formats on individual pads 31 32- inspect and modify internal data routing between pads of the same entity 33 34Sub-device character device nodes, conventionally named 35``/dev/v4l-subdev*``, use major number 81. 36 37Drivers may opt to limit the sub-device character devices to only expose 38operations that do not modify the device state. In such a case the sub-devices 39are referred to as ``read-only`` in the rest of this documentation, and the 40related restrictions are documented in individual ioctls. 41 42 43Controls 44======== 45 46Most V4L2 controls are implemented by sub-device hardware. Drivers 47usually merge all controls and expose them through video device nodes. 48Applications can control all sub-devices through a single interface. 49 50Complex devices sometimes implement the same control in different pieces 51of hardware. This situation is common in embedded platforms, where both 52sensors and image processing hardware implement identical functions, 53such as contrast adjustment, white balance or faulty pixels correction. 54As the V4L2 controls API doesn't support several identical controls in a 55single device, all but one of the identical controls are hidden. 56 57Applications can access those hidden controls through the sub-device 58node with the V4L2 control API described in :ref:`control`. The ioctls 59behave identically as when issued on V4L2 device nodes, with the 60exception that they deal only with controls implemented in the 61sub-device. 62 63Depending on the driver, those controls might also be exposed through 64one (or several) V4L2 device nodes. 65 66 67Events 68====== 69 70V4L2 sub-devices can notify applications of events as described in 71:ref:`event`. The API behaves identically as when used on V4L2 device 72nodes, with the exception that it only deals with events generated by 73the sub-device. Depending on the driver, those events might also be 74reported on one (or several) V4L2 device nodes. 75 76 77.. _pad-level-formats: 78 79Pad-level Formats 80================= 81 82.. warning:: 83 84 Pad-level formats are only applicable to very complex devices that 85 need to expose low-level format configuration to user space. Generic 86 V4L2 applications do *not* need to use the API described in this 87 section. 88 89.. note:: 90 91 For the purpose of this section, the term *format* means the 92 combination of media bus data format, frame width and frame height. 93 94Image formats are typically negotiated on video capture and output 95devices using the format and 96:ref:`selection <VIDIOC_SUBDEV_G_SELECTION>` ioctls. The driver is 97responsible for configuring every block in the video pipeline according 98to the requested format at the pipeline input and/or output. 99 100For complex devices, such as often found in embedded systems, identical 101image sizes at the output of a pipeline can be achieved using different 102hardware configurations. One such example is shown on 103:ref:`pipeline-scaling`, where image scaling can be performed on both 104the video sensor and the host image processing hardware. 105 106 107.. _pipeline-scaling: 108 109.. kernel-figure:: pipeline.dot 110 :alt: pipeline.dot 111 :align: center 112 113 Image Format Negotiation on Pipelines 114 115 High quality and high speed pipeline configuration 116 117 118 119The sensor scaler is usually of less quality than the host scaler, but 120scaling on the sensor is required to achieve higher frame rates. 121Depending on the use case (quality vs. speed), the pipeline must be 122configured differently. Applications need to configure the formats at 123every point in the pipeline explicitly. 124 125Drivers that implement the :ref:`media API <media-controller-intro>` 126can expose pad-level image format configuration to applications. When 127they do, applications can use the 128:ref:`VIDIOC_SUBDEV_G_FMT <VIDIOC_SUBDEV_G_FMT>` and 129:ref:`VIDIOC_SUBDEV_S_FMT <VIDIOC_SUBDEV_G_FMT>` ioctls. to 130negotiate formats on a per-pad basis. 131 132Applications are responsible for configuring coherent parameters on the 133whole pipeline and making sure that connected pads have compatible 134formats. The pipeline is checked for formats mismatch at 135:ref:`VIDIOC_STREAMON <VIDIOC_STREAMON>` time, and an ``EPIPE`` error 136code is then returned if the configuration is invalid. 137 138Pad-level image format configuration support can be tested by calling 139the :ref:`VIDIOC_SUBDEV_G_FMT` ioctl on pad 1400. If the driver returns an ``EINVAL`` error code pad-level format 141configuration is not supported by the sub-device. 142 143 144Format Negotiation 145------------------ 146 147Acceptable formats on pads can (and usually do) depend on a number of 148external parameters, such as formats on other pads, active links, or 149even controls. Finding a combination of formats on all pads in a video 150pipeline, acceptable to both application and driver, can't rely on 151formats enumeration only. A format negotiation mechanism is required. 152 153Central to the format negotiation mechanism are the get/set format 154operations. When called with the ``which`` argument set to 155:ref:`V4L2_SUBDEV_FORMAT_TRY <VIDIOC_SUBDEV_G_FMT>`, the 156:ref:`VIDIOC_SUBDEV_G_FMT <VIDIOC_SUBDEV_G_FMT>` and 157:ref:`VIDIOC_SUBDEV_S_FMT <VIDIOC_SUBDEV_G_FMT>` ioctls operate on 158a set of formats parameters that are not connected to the hardware 159configuration. Modifying those 'try' formats leaves the device state 160untouched (this applies to both the software state stored in the driver 161and the hardware state stored in the device itself). 162 163While not kept as part of the device state, try formats are stored in 164the sub-device file handles. A 165:ref:`VIDIOC_SUBDEV_G_FMT <VIDIOC_SUBDEV_G_FMT>` call will return 166the last try format set *on the same sub-device file handle*. Several 167applications querying the same sub-device at the same time will thus not 168interact with each other. 169 170To find out whether a particular format is supported by the device, 171applications use the 172:ref:`VIDIOC_SUBDEV_S_FMT <VIDIOC_SUBDEV_G_FMT>` ioctl. Drivers 173verify and, if needed, change the requested ``format`` based on device 174requirements and return the possibly modified value. Applications can 175then choose to try a different format or accept the returned value and 176continue. 177 178Formats returned by the driver during a negotiation iteration are 179guaranteed to be supported by the device. In particular, drivers 180guarantee that a returned format will not be further changed if passed 181to an :ref:`VIDIOC_SUBDEV_S_FMT <VIDIOC_SUBDEV_G_FMT>` call as-is 182(as long as external parameters, such as formats on other pads or links' 183configuration are not changed). 184 185Drivers automatically propagate formats inside sub-devices. When a try 186or active format is set on a pad, corresponding formats on other pads of 187the same sub-device can be modified by the driver. Drivers are free to 188modify formats as required by the device. However, they should comply 189with the following rules when possible: 190 191- Formats should be propagated from sink pads to source pads. Modifying 192 a format on a source pad should not modify the format on any sink 193 pad. 194 195- Sub-devices that scale frames using variable scaling factors should 196 reset the scale factors to default values when sink pads formats are 197 modified. If the 1:1 scaling ratio is supported, this means that 198 source pads formats should be reset to the sink pads formats. 199 200Formats are not propagated across links, as that would involve 201propagating them from one sub-device file handle to another. 202Applications must then take care to configure both ends of every link 203explicitly with compatible formats. Identical formats on the two ends of 204a link are guaranteed to be compatible. Drivers are free to accept 205different formats matching device requirements as being compatible. 206 207:ref:`sample-pipeline-config` shows a sample configuration sequence 208for the pipeline described in :ref:`pipeline-scaling` (table columns 209list entity names and pad numbers). 210 211 212.. raw:: latex 213 214 \begingroup 215 \scriptsize 216 \setlength{\tabcolsep}{2pt} 217 218.. tabularcolumns:: |p{2.0cm}|p{2.1cm}|p{2.1cm}|p{2.1cm}|p{2.1cm}|p{2.1cm}|p{2.1cm}| 219 220.. _sample-pipeline-config: 221 222.. flat-table:: Sample Pipeline Configuration 223 :header-rows: 1 224 :stub-columns: 0 225 :widths: 5 5 5 5 5 5 5 226 227 * - 228 - Sensor/0 229 230 format 231 - Frontend/0 232 233 format 234 - Frontend/1 235 236 format 237 - Scaler/0 238 239 format 240 - Scaler/0 241 242 compose selection rectangle 243 - Scaler/1 244 245 format 246 * - Initial state 247 - 2048x1536 248 249 SGRBG8_1X8 250 - (default) 251 - (default) 252 - (default) 253 - (default) 254 - (default) 255 * - Configure frontend sink format 256 - 2048x1536 257 258 SGRBG8_1X8 259 - *2048x1536* 260 261 *SGRBG8_1X8* 262 - *2046x1534* 263 264 *SGRBG8_1X8* 265 - (default) 266 - (default) 267 - (default) 268 * - Configure scaler sink format 269 - 2048x1536 270 271 SGRBG8_1X8 272 - 2048x1536 273 274 SGRBG8_1X8 275 - 2046x1534 276 277 SGRBG8_1X8 278 - *2046x1534* 279 280 *SGRBG8_1X8* 281 - *0,0/2046x1534* 282 - *2046x1534* 283 284 *SGRBG8_1X8* 285 * - Configure scaler sink compose selection 286 - 2048x1536 287 288 SGRBG8_1X8 289 - 2048x1536 290 291 SGRBG8_1X8 292 - 2046x1534 293 294 SGRBG8_1X8 295 - 2046x1534 296 297 SGRBG8_1X8 298 - *0,0/1280x960* 299 - *1280x960* 300 301 *SGRBG8_1X8* 302 303.. raw:: latex 304 305 \endgroup 306 3071. Initial state. The sensor source pad format is set to its native 3MP 308 size and V4L2_MBUS_FMT_SGRBG8_1X8 media bus code. Formats on the 309 host frontend and scaler sink and source pads have the default 310 values, as well as the compose rectangle on the scaler's sink pad. 311 3122. The application configures the frontend sink pad format's size to 313 2048x1536 and its media bus code to V4L2_MBUS_FMT_SGRBG_1X8. The 314 driver propagates the format to the frontend source pad. 315 3163. The application configures the scaler sink pad format's size to 317 2046x1534 and the media bus code to V4L2_MBUS_FMT_SGRBG_1X8 to 318 match the frontend source size and media bus code. The media bus code 319 on the sink pad is set to V4L2_MBUS_FMT_SGRBG_1X8. The driver 320 propagates the size to the compose selection rectangle on the 321 scaler's sink pad, and the format to the scaler source pad. 322 3234. The application configures the size of the compose selection 324 rectangle of the scaler's sink pad 1280x960. The driver propagates 325 the size to the scaler's source pad format. 326 327When satisfied with the try results, applications can set the active 328formats by setting the ``which`` argument to 329``V4L2_SUBDEV_FORMAT_ACTIVE``. Active formats are changed exactly as try 330formats by drivers. To avoid modifying the hardware state during format 331negotiation, applications should negotiate try formats first and then 332modify the active settings using the try formats returned during the 333last negotiation iteration. This guarantees that the active format will 334be applied as-is by the driver without being modified. 335 336 337.. _v4l2-subdev-selections: 338 339Selections: cropping, scaling and composition 340--------------------------------------------- 341 342Many sub-devices support cropping frames on their input or output pads 343(or possible even on both). Cropping is used to select the area of 344interest in an image, typically on an image sensor or a video decoder. 345It can also be used as part of digital zoom implementations to select 346the area of the image that will be scaled up. 347 348Crop settings are defined by a crop rectangle and represented in a 349struct :c:type:`v4l2_rect` by the coordinates of the top 350left corner and the rectangle size. Both the coordinates and sizes are 351expressed in pixels. 352 353As for pad formats, drivers store try and active rectangles for the 354selection targets :ref:`v4l2-selections-common`. 355 356On sink pads, cropping is applied relative to the current pad format. 357The pad format represents the image size as received by the sub-device 358from the previous block in the pipeline, and the crop rectangle 359represents the sub-image that will be transmitted further inside the 360sub-device for processing. 361 362The scaling operation changes the size of the image by scaling it to new 363dimensions. The scaling ratio isn't specified explicitly, but is implied 364from the original and scaled image sizes. Both sizes are represented by 365struct :c:type:`v4l2_rect`. 366 367Scaling support is optional. When supported by a subdev, the crop 368rectangle on the subdev's sink pad is scaled to the size configured 369using the 370:ref:`VIDIOC_SUBDEV_S_SELECTION <VIDIOC_SUBDEV_G_SELECTION>` IOCTL 371using ``V4L2_SEL_TGT_COMPOSE`` selection target on the same pad. If the 372subdev supports scaling but not composing, the top and left values are 373not used and must always be set to zero. 374 375On source pads, cropping is similar to sink pads, with the exception 376that the source size from which the cropping is performed, is the 377COMPOSE rectangle on the sink pad. In both sink and source pads, the 378crop rectangle must be entirely contained inside the source image size 379for the crop operation. 380 381The drivers should always use the closest possible rectangle the user 382requests on all selection targets, unless specifically told otherwise. 383``V4L2_SEL_FLAG_GE`` and ``V4L2_SEL_FLAG_LE`` flags may be used to round 384the image size either up or down. :ref:`v4l2-selection-flags` 385 386 387Types of selection targets 388-------------------------- 389 390 391Actual targets 392^^^^^^^^^^^^^^ 393 394Actual targets (without a postfix) reflect the actual hardware 395configuration at any point of time. There is a BOUNDS target 396corresponding to every actual target. 397 398 399BOUNDS targets 400^^^^^^^^^^^^^^ 401 402BOUNDS targets is the smallest rectangle that contains all valid actual 403rectangles. It may not be possible to set the actual rectangle as large 404as the BOUNDS rectangle, however. This may be because e.g. a sensor's 405pixel array is not rectangular but cross-shaped or round. The maximum 406size may also be smaller than the BOUNDS rectangle. 407 408 409.. _format-propagation: 410 411Order of configuration and format propagation 412--------------------------------------------- 413 414Inside subdevs, the order of image processing steps will always be from 415the sink pad towards the source pad. This is also reflected in the order 416in which the configuration must be performed by the user: the changes 417made will be propagated to any subsequent stages. If this behaviour is 418not desired, the user must set ``V4L2_SEL_FLAG_KEEP_CONFIG`` flag. This 419flag causes no propagation of the changes are allowed in any 420circumstances. This may also cause the accessed rectangle to be adjusted 421by the driver, depending on the properties of the underlying hardware. 422 423The coordinates to a step always refer to the actual size of the 424previous step. The exception to this rule is the sink compose 425rectangle, which refers to the sink compose bounds rectangle --- if it 426is supported by the hardware. 427 4281. Sink pad format. The user configures the sink pad format. This format 429 defines the parameters of the image the entity receives through the 430 pad for further processing. 431 4322. Sink pad actual crop selection. The sink pad crop defines the crop 433 performed to the sink pad format. 434 4353. Sink pad actual compose selection. The size of the sink pad compose 436 rectangle defines the scaling ratio compared to the size of the sink 437 pad crop rectangle. The location of the compose rectangle specifies 438 the location of the actual sink compose rectangle in the sink compose 439 bounds rectangle. 440 4414. Source pad actual crop selection. Crop on the source pad defines crop 442 performed to the image in the sink compose bounds rectangle. 443 4445. Source pad format. The source pad format defines the output pixel 445 format of the subdev, as well as the other parameters with the 446 exception of the image width and height. Width and height are defined 447 by the size of the source pad actual crop selection. 448 449Accessing any of the above rectangles not supported by the subdev will 450return ``EINVAL``. Any rectangle referring to a previous unsupported 451rectangle coordinates will instead refer to the previous supported 452rectangle. For example, if sink crop is not supported, the compose 453selection will refer to the sink pad format dimensions instead. 454 455 456.. _subdev-image-processing-crop: 457 458.. kernel-figure:: subdev-image-processing-crop.svg 459 :alt: subdev-image-processing-crop.svg 460 :align: center 461 462 **Figure 4.5. Image processing in subdevs: simple crop example** 463 464In the above example, the subdev supports cropping on its sink pad. To 465configure it, the user sets the media bus format on the subdev's sink 466pad. Now the actual crop rectangle can be set on the sink pad --- the 467location and size of this rectangle reflect the location and size of a 468rectangle to be cropped from the sink format. The size of the sink crop 469rectangle will also be the size of the format of the subdev's source 470pad. 471 472 473.. _subdev-image-processing-scaling-multi-source: 474 475.. kernel-figure:: subdev-image-processing-scaling-multi-source.svg 476 :alt: subdev-image-processing-scaling-multi-source.svg 477 :align: center 478 479 **Figure 4.6. Image processing in subdevs: scaling with multiple sources** 480 481In this example, the subdev is capable of first cropping, then scaling 482and finally cropping for two source pads individually from the resulting 483scaled image. The location of the scaled image in the cropped image is 484ignored in sink compose target. Both of the locations of the source crop 485rectangles refer to the sink scaling rectangle, independently cropping 486an area at location specified by the source crop rectangle from it. 487 488 489.. _subdev-image-processing-full: 490 491.. kernel-figure:: subdev-image-processing-full.svg 492 :alt: subdev-image-processing-full.svg 493 :align: center 494 495 **Figure 4.7. Image processing in subdevs: scaling and composition with multiple sinks and sources** 496 497The subdev driver supports two sink pads and two source pads. The images 498from both of the sink pads are individually cropped, then scaled and 499further composed on the composition bounds rectangle. From that, two 500independent streams are cropped and sent out of the subdev from the 501source pads. 502 503 504.. toctree:: 505 :maxdepth: 1 506 507 subdev-formats 508 509Streams, multiplexed media pads and internal routing 510---------------------------------------------------- 511 512Simple V4L2 sub-devices do not support multiple, unrelated video streams, 513and only a single stream can pass through a media link and a media pad. 514Thus each pad contains a format and selection configuration for that 515single stream. A subdev can do stream processing and split a stream into 516two or compose two streams into one, but the inputs and outputs for the 517subdev are still a single stream per pad. 518 519Some hardware, e.g. MIPI CSI-2, support multiplexed streams, that is, multiple 520data streams are transmitted on the same bus, which is represented by a media 521link connecting a transmitter source pad with a sink pad on the receiver. For 522example, a camera sensor can produce two distinct streams, a pixel stream and a 523metadata stream, which are transmitted on the multiplexed data bus, represented 524by a media link which connects the single sensor's source pad with the receiver 525sink pad. The stream-aware receiver will de-multiplex the streams received on 526the its sink pad and allows to route them individually to one of its source 527pads. 528 529Subdevice drivers that support multiplexed streams are compatible with 530non-multiplexed subdev drivers, but, of course, require a routing configuration 531where the link between those two types of drivers contains only a single 532stream. 533 534Understanding streams 535^^^^^^^^^^^^^^^^^^^^^ 536 537A stream is a stream of content (e.g. pixel data or metadata) flowing through 538the media pipeline from a source (e.g. a sensor) towards the final sink (e.g. a 539receiver and demultiplexer in a SoC). Each media link carries all the enabled 540streams from one end of the link to the other, and sub-devices have routing 541tables which describe how the incoming streams from sink pads are routed to the 542source pads. 543 544A stream ID is a media pad-local identifier for a stream. Streams IDs of 545the same stream must be equal on both ends of a link. In other words, 546a particular stream ID must exist on both sides of a media 547link, but another stream ID can be used for the same stream at the other side 548of the sub-device. 549 550A stream at a specific point in the media pipeline is identified by the 551sub-device and a (pad, stream) pair. For sub-devices that do not support 552multiplexed streams the 'stream' field is always 0. 553 554Interaction between routes, streams, formats and selections 555^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ 556 557The addition of streams to the V4L2 sub-device interface moves the sub-device 558formats and selections from pads to (pad, stream) pairs. Besides the 559usual pad, also the stream ID needs to be provided for setting formats and 560selections. The order of configuring formats and selections along a stream is 561the same as without streams (see :ref:`format-propagation`). 562 563Instead of the sub-device wide merging of streams from all sink pads 564towards all source pads, data flows for each route are separate from each 565other. Any number of routes from streams on sink pads towards streams on 566source pads is allowed, to the extent supported by drivers. For every 567stream on a source pad, however, only a single route is allowed. 568 569Any configurations of a stream within a pad, such as format or selections, 570are independent of similar configurations on other streams. This is 571subject to change in the future. 572 573Configuring streams 574^^^^^^^^^^^^^^^^^^^ 575 576The configuration of the streams is done individually for each sub-device and 577the validity of the streams between sub-devices is validated when the pipeline 578is started. 579 580There are three steps in configuring the streams: 581 5821. Set up links. Connect the pads between sub-devices using the 583 :ref:`Media Controller API <media_controller>` 584 5852. Streams. Streams are declared and their routing is configured by setting the 586 routing table for the sub-device using :ref:`VIDIOC_SUBDEV_S_ROUTING 587 <VIDIOC_SUBDEV_G_ROUTING>` ioctl. Note that setting the routing table will 588 reset formats and selections in the sub-device to default values. 589 5903. Configure formats and selections. Formats and selections of each stream are 591 configured separately as documented for plain sub-devices in 592 :ref:`format-propagation`. The stream ID is set to the same stream ID 593 associated with either sink or source pads of routes configured using the 594 :ref:`VIDIOC_SUBDEV_S_ROUTING <VIDIOC_SUBDEV_G_ROUTING>` ioctl. 595 596Multiplexed streams setup example 597^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ 598 599A simple example of a multiplexed stream setup might be as follows: 600 601- Two identical sensors (Sensor A and Sensor B). Each sensor has a single source 602 pad (pad 0) which carries a pixel data stream. 603 604- Multiplexer bridge (Bridge). The bridge has two sink pads, connected to the 605 sensors (pads 0, 1), and one source pad (pad 2), which outputs two streams. 606 607- Receiver in the SoC (Receiver). The receiver has a single sink pad (pad 0), 608 connected to the bridge, and two source pads (pads 1-2), going to the DMA 609 engine. The receiver demultiplexes the incoming streams to the source pads. 610 611- DMA Engines in the SoC (DMA Engine), one for each stream. Each DMA engine is 612 connected to a single source pad in the receiver. 613 614The sensors, the bridge and the receiver are modeled as V4L2 sub-devices, 615exposed to userspace via /dev/v4l-subdevX device nodes. The DMA engines are 616modeled as V4L2 devices, exposed to userspace via /dev/videoX nodes. 617 618To configure this pipeline, the userspace must take the following steps: 619 6201. Set up media links between entities: connect the sensors to the bridge, 621 bridge to the receiver, and the receiver to the DMA engines. This step does 622 not differ from normal non-multiplexed media controller setup. 623 6242. Configure routing 625 626.. flat-table:: Bridge routing table 627 :header-rows: 1 628 629 * - Sink Pad/Stream 630 - Source Pad/Stream 631 - Routing Flags 632 - Comments 633 * - 0/0 634 - 2/0 635 - V4L2_SUBDEV_ROUTE_FL_ACTIVE 636 - Pixel data stream from Sensor A 637 * - 1/0 638 - 2/1 639 - V4L2_SUBDEV_ROUTE_FL_ACTIVE 640 - Pixel data stream from Sensor B 641 642.. flat-table:: Receiver routing table 643 :header-rows: 1 644 645 * - Sink Pad/Stream 646 - Source Pad/Stream 647 - Routing Flags 648 - Comments 649 * - 0/0 650 - 1/0 651 - V4L2_SUBDEV_ROUTE_FL_ACTIVE 652 - Pixel data stream from Sensor A 653 * - 0/1 654 - 2/0 655 - V4L2_SUBDEV_ROUTE_FL_ACTIVE 656 - Pixel data stream from Sensor B 657 6583. Configure formats and selections 659 660 After configuring routing, the next step is configuring the formats and 661 selections for the streams. This is similar to performing this step without 662 streams, with just one exception: the ``stream`` field needs to be assigned 663 to the value of the stream ID. 664 665 A common way to accomplish this is to start from the sensors and propagate 666 the configurations along the stream towards the receiver, using 667 :ref:`VIDIOC_SUBDEV_S_FMT <VIDIOC_SUBDEV_G_FMT>` ioctls to configure each 668 stream endpoint in each sub-device. 669