On Mon, Jan 4, 2021 at 10:58 AM Rob Herring <robh@xxxxxxxxxx> wrote: > > Convert video-interfaces.txt to DT schema. As it contains a mixture of > device level and endpoint properties, split it up into 2 schemas. Ping! Can this please be applied to the media tree so I can tell folks to use it in reviews of media bindings. > Binding schemas will need to reference both the graph.yaml and > video-interfaces.yaml schemas. The exact schema depends on how many > ports and endpoints for the binding. A single port with a single > endpoint looks similar to this: > > port: > $ref: /schemas/graph.yaml#/$defs/port-base > > properties: > endpoint: > $ref: video-interfaces.yaml# > unevaluatedProperties: false > > properties: > bus-width: > enum: [ 8, 10, 12, 16 ] > > pclk-sample: true > hsync-active: true > vsync-active: true > > required: > - bus-width > > additionalProperties: false > > Acked-by: Sakari Ailus <sakari.ailus@xxxxxxxxxxxxxxx> > Acked-by: Jacopo Mondi <jacopo@xxxxxxxxxx> > Acked-by: Guennadi Liakhovetski <g.liakhovetski@xxxxxx> > Acked-by: Hans Verkuil <hverkuil-cisco@xxxxxxxxx> > Reviewed-by: Laurent Pinchart <laurent.pinchart@xxxxxxxxxxxxxxxx> > Signed-off-by: Rob Herring <robh@xxxxxxxxxx> > --- > > v4: > - drop graph.txt ref > - s/Bt.656/BT.656/ > - Replace Guennadi with Laurent as maintainer > > v3: > - Support up to 9 physical lanes > - Set lane-polarities array bounds > --- > .../media/video-interface-devices.yaml | 406 +++++++++++ > .../bindings/media/video-interfaces.txt | 640 +----------------- > .../bindings/media/video-interfaces.yaml | 344 ++++++++++ > 3 files changed, 751 insertions(+), 639 deletions(-) > create mode 100644 Documentation/devicetree/bindings/media/video-interface-devices.yaml > create mode 100644 Documentation/devicetree/bindings/media/video-interfaces.yaml > > diff --git a/Documentation/devicetree/bindings/media/video-interface-devices.yaml b/Documentation/devicetree/bindings/media/video-interface-devices.yaml > new file mode 100644 > index 000000000000..4527f56a5a6e > --- /dev/null > +++ b/Documentation/devicetree/bindings/media/video-interface-devices.yaml > @@ -0,0 +1,406 @@ > +# SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause) > +%YAML 1.2 > +--- > +$id: http://devicetree.org/schemas/media/video-interface-devices.yaml# > +$schema: http://devicetree.org/meta-schemas/core.yaml# > + > +title: Common bindings for video receiver and transmitter devices > + > +maintainers: > + - Jacopo Mondi <jacopo@xxxxxxxxxx> > + - Sakari Ailus <sakari.ailus@xxxxxxxxxxxxxxx> > + > +properties: > + flash-leds: > + $ref: /schemas/types.yaml#/definitions/phandle-array > + description: > + An array of phandles, each referring to a flash LED, a sub-node of the LED > + driver device node. > + > + lens-focus: > + $ref: /schemas/types.yaml#/definitions/phandle > + description: > + A phandle to the node of the focus lens controller. > + > + rotation: > + $ref: /schemas/types.yaml#/definitions/uint32 > + enum: [ 0, 90, 180, 270 ] > + description: | > + The camera rotation is expressed as the angular difference in degrees > + between two reference systems, one relative to the camera module, and one > + defined on the external world scene to be captured when projected on the > + image sensor pixel array. > + > + A camera sensor has a 2-dimensional reference system 'Rc' defined by its > + pixel array read-out order. The origin is set to the first pixel being > + read out, the X-axis points along the column read-out direction towards > + the last columns, and the Y-axis along the row read-out direction towards > + the last row. > + > + A typical example for a sensor with a 2592x1944 pixel array matrix > + observed from the front is: > + > + 2591 X-axis 0 > + <------------------------+ 0 > + .......... ... ..........! > + .......... ... ..........! Y-axis > + ... ! > + .......... ... ..........! > + .......... ... ..........! 1943 > + V > + > + The external world scene reference system 'Rs' is a 2-dimensional > + reference system on the focal plane of the camera module. The origin is > + placed on the top-left corner of the visible scene, the X-axis points > + towards the right, and the Y-axis points towards the bottom of the scene. > + The top, bottom, left and right directions are intentionally not defined > + and depend on the environment in which the camera is used. > + > + A typical example of a (very common) picture of a shark swimming from left > + to right, as seen from the camera, is: > + > + 0 X-axis > + 0 +-------------------------------------> > + ! > + ! > + ! > + ! |\____)\___ > + ! ) _____ __`< > + ! |/ )/ > + ! > + ! > + ! > + V > + Y-axis > + > + with the reference system 'Rs' placed on the camera focal plane: > + > + ¸.·˙! > + ¸.·˙ ! > + _ ¸.·˙ ! > + +-/ \-+¸.·˙ ! > + | (o) | ! Camera focal plane > + +-----+˙·.¸ ! > + ˙·.¸ ! > + ˙·.¸ ! > + ˙·.¸! > + > + When projected on the sensor's pixel array, the image and the associated > + reference system 'Rs' are typically (but not always) inverted, due to the > + camera module's lens optical inversion effect. > + > + Assuming the above represented scene of the swimming shark, the lens > + inversion projects the scene and its reference system onto the sensor > + pixel array, seen from the front of the camera sensor, as follows: > + > + Y-axis > + ^ > + ! > + ! > + ! > + ! |\_____)\__ > + ! ) ____ ___.< > + ! |/ )/ > + ! > + ! > + ! > + 0 +-------------------------------------> > + 0 X-axis > + > + Note the shark being upside-down. > + > + The resulting projected reference system is named 'Rp'. > + > + The camera rotation property is then defined as the angular difference in > + the counter-clockwise direction between the camera reference system 'Rc' > + and the projected scene reference system 'Rp'. It is expressed in degrees > + as a number in the range [0, 360[. > + > + Examples > + > + 0 degrees camera rotation: > + > + > + Y-Rp > + ^ > + Y-Rc ! > + ^ ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! 0 +-------------------------------------> > + ! 0 X-Rp > + 0 +-------------------------------------> > + 0 X-Rc > + > + > + X-Rc 0 > + <------------------------------------+ 0 > + X-Rp 0 ! > + <------------------------------------+ 0 ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! V > + ! Y-Rc > + V > + Y-Rp > + > + 90 degrees camera rotation: > + > + 0 Y-Rc > + 0 +--------------------> > + ! Y-Rp > + ! ^ > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! 0 +-------------------------------------> > + ! 0 X-Rp > + ! > + ! > + ! > + ! > + V > + X-Rc > + > + 180 degrees camera rotation: > + > + 0 > + <------------------------------------+ 0 > + X-Rc ! > + Y-Rp ! > + ^ ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! V > + ! Y-Rc > + 0 +-------------------------------------> > + 0 X-Rp > + > + 270 degrees camera rotation: > + > + 0 Y-Rc > + 0 +--------------------> > + ! 0 > + ! <-----------------------------------+ 0 > + ! X-Rp ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! ! > + ! V > + ! Y-Rp > + ! > + ! > + ! > + ! > + V > + X-Rc > + > + > + Example one - Webcam > + > + A camera module installed on the user facing part of a laptop screen > + casing used for video calls. The captured images are meant to be displayed > + in landscape mode (width > height) on the laptop screen. > + > + The camera is typically mounted upside-down to compensate the lens optical > + inversion effect: > + > + Y-Rp > + Y-Rc ^ > + ^ ! > + ! ! > + ! ! |\_____)\__ > + ! ! ) ____ ___.< > + ! ! |/ )/ > + ! ! > + ! ! > + ! ! > + ! 0 +-------------------------------------> > + ! 0 X-Rp > + 0 +-------------------------------------> > + 0 X-Rc > + > + The two reference systems are aligned, the resulting camera rotation is > + 0 degrees, no rotation correction needs to be applied to the resulting > + image once captured to memory buffers to correctly display it to users: > + > + +--------------------------------------+ > + ! ! > + ! ! > + ! ! > + ! |\____)\___ ! > + ! ) _____ __`< ! > + ! |/ )/ ! > + ! ! > + ! ! > + ! ! > + +--------------------------------------+ > + > + If the camera sensor is not mounted upside-down to compensate for the lens > + optical inversion, the two reference systems will not be aligned, with > + 'Rp' being rotated 180 degrees relatively to 'Rc': > + > + > + X-Rc 0 > + <------------------------------------+ 0 > + ! > + Y-Rp ! > + ^ ! > + ! ! > + ! |\_____)\__ ! > + ! ) ____ ___.< ! > + ! |/ )/ ! > + ! ! > + ! ! > + ! V > + ! Y-Rc > + 0 +-------------------------------------> > + 0 X-Rp > + > + The image once captured to memory will then be rotated by 180 degrees: > + > + +--------------------------------------+ > + ! ! > + ! ! > + ! ! > + ! __/(_____/| ! > + ! >.___ ____ ( ! > + ! \( \| ! > + ! ! > + ! ! > + ! ! > + +--------------------------------------+ > + > + A software rotation correction of 180 degrees should be applied to > + correctly display the image: > + > + +--------------------------------------+ > + ! ! > + ! ! > + ! ! > + ! |\____)\___ ! > + ! ) _____ __`< ! > + ! |/ )/ ! > + ! ! > + ! ! > + ! ! > + +--------------------------------------+ > + > + Example two - Phone camera > + > + A camera installed on the back side of a mobile device facing away from > + the user. The captured images are meant to be displayed in portrait mode > + (height > width) to match the device screen orientation and the device > + usage orientation used when taking the picture. > + > + The camera sensor is typically mounted with its pixel array longer side > + aligned to the device longer side, upside-down mounted to compensate for > + the lens optical inversion effect: > + > + 0 Y-Rc > + 0 +--------------------> > + ! Y-Rp > + ! ^ > + ! ! > + ! ! > + ! ! > + ! ! |\_____)\__ > + ! ! ) ____ ___.< > + ! ! |/ )/ > + ! ! > + ! ! > + ! ! > + ! 0 +-------------------------------------> > + ! 0 X-Rp > + ! > + ! > + ! > + ! > + V > + X-Rc > + > + The two reference systems are not aligned and the 'Rp' reference system is > + rotated by 90 degrees in the counter-clockwise direction relatively to the > + 'Rc' reference system. > + > + The image once captured to memory will be rotated: > + > + +-------------------------------------+ > + | _ _ | > + | \ / | > + | | | | > + | | | | > + | | > | > + | < | | > + | | | | > + | . | > + | V | > + +-------------------------------------+ > + > + A correction of 90 degrees in counter-clockwise direction has to be > + applied to correctly display the image in portrait mode on the device > + screen: > + > + +--------------------+ > + | | > + | | > + | | > + | | > + | | > + | | > + | |\____)\___ | > + | ) _____ __`< | > + | |/ )/ | > + | | > + | | > + | | > + | | > + | | > + +--------------------+ > + > + orientation: > + description: > + The orientation of a device (typically an image sensor or a flash LED) > + describing its mounting position relative to the usage orientation of the > + system where the device is installed on. > + $ref: /schemas/types.yaml#/definitions/uint32 > + enum: > + # Front. The device is mounted on the front facing side of the system. For > + # mobile devices such as smartphones, tablets and laptops the front side > + # is the user facing side. > + - 0 > + # Back. The device is mounted on the back side of the system, which is > + # defined as the opposite side of the front facing one. > + - 1 > + # External. The device is not attached directly to the system but is > + # attached in a way that allows it to move freely. > + - 2 > + > +additionalProperties: true > + > +... > diff --git a/Documentation/devicetree/bindings/media/video-interfaces.txt b/Documentation/devicetree/bindings/media/video-interfaces.txt > index 3920f25a9123..8fcf5f52bf5b 100644 > --- a/Documentation/devicetree/bindings/media/video-interfaces.txt > +++ b/Documentation/devicetree/bindings/media/video-interfaces.txt > @@ -1,639 +1 @@ > -Common bindings for video receiver and transmitter interfaces > - > -General concept > ---------------- > - > -Video data pipelines usually consist of external devices, e.g. camera sensors, > -controlled over an I2C, SPI or UART bus, and SoC internal IP blocks, including > -video DMA engines and video data processors. > - > -SoC internal blocks are described by DT nodes, placed similarly to other SoC > -blocks. External devices are represented as child nodes of their respective > -bus controller nodes, e.g. I2C. > - > -Data interfaces on all video devices are described by their child 'port' nodes. > -Configuration of a port depends on other devices participating in the data > -transfer and is described by 'endpoint' subnodes. > - > -device { > - ... > - ports { > - #address-cells = <1>; > - #size-cells = <0>; > - > - port@0 { > - ... > - endpoint@0 { ... }; > - endpoint@1 { ... }; > - }; > - port@1 { ... }; > - }; > -}; > - > -If a port can be configured to work with more than one remote device on the same > -bus, an 'endpoint' child node must be provided for each of them. If more than > -one port is present in a device node or there is more than one endpoint at a > -port, or port node needs to be associated with a selected hardware interface, > -a common scheme using '#address-cells', '#size-cells' and 'reg' properties is > -used. > - > -All 'port' nodes can be grouped under optional 'ports' node, which allows to > -specify #address-cells, #size-cells properties independently for the 'port' > -and 'endpoint' nodes and any child device nodes a device might have. > - > -Two 'endpoint' nodes are linked with each other through their 'remote-endpoint' > -phandles. An endpoint subnode of a device contains all properties needed for > -configuration of this device for data exchange with other device. In most > -cases properties at the peer 'endpoint' nodes will be identical, however they > -might need to be different when there is any signal modifications on the bus > -between two devices, e.g. there are logic signal inverters on the lines. > - > -It is allowed for multiple endpoints at a port to be active simultaneously, > -where supported by a device. For example, in case where a data interface of > -a device is partitioned into multiple data busses, e.g. 16-bit input port > -divided into two separate ITU-R BT.656 8-bit busses. In such case bus-width > -and data-shift properties can be used to assign physical data lines to each > -endpoint node (logical bus). > - > -Documenting bindings for devices > --------------------------------- > - > -All required and optional bindings the device supports shall be explicitly > -documented in device DT binding documentation. This also includes port and > -endpoint nodes for the device, including unit-addresses and reg properties where > -relevant. > - > -Please also see Documentation/devicetree/bindings/graph.txt . > - > -Required properties > -------------------- > - > -If there is more than one 'port' or more than one 'endpoint' node or 'reg' > -property is present in port and/or endpoint nodes the following properties > -are required in a relevant parent node: > - > - - #address-cells : number of cells required to define port/endpoint > - identifier, should be 1. > - - #size-cells : should be zero. > - > - > -Optional properties > -------------------- > - > -- flash-leds: An array of phandles, each referring to a flash LED, a sub-node > - of the LED driver device node. > - > -- lens-focus: A phandle to the node of the focus lens controller. > - > -- rotation: The camera rotation is expressed as the angular difference in > - degrees between two reference systems, one relative to the camera module, and > - one defined on the external world scene to be captured when projected on the > - image sensor pixel array. > - > - A camera sensor has a 2-dimensional reference system 'Rc' defined by > - its pixel array read-out order. The origin is set to the first pixel > - being read out, the X-axis points along the column read-out direction > - towards the last columns, and the Y-axis along the row read-out > - direction towards the last row. > - > - A typical example for a sensor with a 2592x1944 pixel array matrix > - observed from the front is: > - > - 2591 X-axis 0 > - <------------------------+ 0 > - .......... ... ..........! > - .......... ... ..........! Y-axis > - ... ! > - .......... ... ..........! > - .......... ... ..........! 1943 > - V > - > - The external world scene reference system 'Rs' is a 2-dimensional > - reference system on the focal plane of the camera module. The origin is > - placed on the top-left corner of the visible scene, the X-axis points > - towards the right, and the Y-axis points towards the bottom of the > - scene. The top, bottom, left and right directions are intentionally not > - defined and depend on the environment in which the camera is used. > - > - A typical example of a (very common) picture of a shark swimming from > - left to right, as seen from the camera, is: > - > - 0 X-axis > - 0 +-------------------------------------> > - ! > - ! > - ! > - ! |\____)\___ > - ! ) _____ __`< > - ! |/ )/ > - ! > - ! > - ! > - V > - Y-axis > - > - with the reference system 'Rs' placed on the camera focal plane: > - > - ¸.·˙! > - ¸.·˙ ! > - _ ¸.·˙ ! > - +-/ \-+¸.·˙ ! > - | (o) | ! Camera focal plane > - +-----+˙·.¸ ! > - ˙·.¸ ! > - ˙·.¸ ! > - ˙·.¸! > - > - When projected on the sensor's pixel array, the image and the associated > - reference system 'Rs' are typically (but not always) inverted, due to > - the camera module's lens optical inversion effect. > - > - Assuming the above represented scene of the swimming shark, the lens > - inversion projects the scene and its reference system onto the sensor > - pixel array, seen from the front of the camera sensor, as follows: > - > - Y-axis > - ^ > - ! > - ! > - ! > - ! |\_____)\__ > - ! ) ____ ___.< > - ! |/ )/ > - ! > - ! > - ! > - 0 +-------------------------------------> > - 0 X-axis > - > - Note the shark being upside-down. > - > - The resulting projected reference system is named 'Rp'. > - > - The camera rotation property is then defined as the angular difference > - in the counter-clockwise direction between the camera reference system > - 'Rc' and the projected scene reference system 'Rp'. It is expressed in > - degrees as a number in the range [0, 360[. > - > - Examples > - > - 0 degrees camera rotation: > - > - > - Y-Rp > - ^ > - Y-Rc ! > - ^ ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! 0 +-------------------------------------> > - ! 0 X-Rp > - 0 +-------------------------------------> > - 0 X-Rc > - > - > - X-Rc 0 > - <------------------------------------+ 0 > - X-Rp 0 ! > - <------------------------------------+ 0 ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! V > - ! Y-Rc > - V > - Y-Rp > - > - 90 degrees camera rotation: > - > - 0 Y-Rc > - 0 +--------------------> > - ! Y-Rp > - ! ^ > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! 0 +-------------------------------------> > - ! 0 X-Rp > - ! > - ! > - ! > - ! > - V > - X-Rc > - > - 180 degrees camera rotation: > - > - 0 > - <------------------------------------+ 0 > - X-Rc ! > - Y-Rp ! > - ^ ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! V > - ! Y-Rc > - 0 +-------------------------------------> > - 0 X-Rp > - > - 270 degrees camera rotation: > - > - 0 Y-Rc > - 0 +--------------------> > - ! 0 > - ! <-----------------------------------+ 0 > - ! X-Rp ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! ! > - ! V > - ! Y-Rp > - ! > - ! > - ! > - ! > - V > - X-Rc > - > - > - Example one - Webcam > - > - A camera module installed on the user facing part of a laptop screen > - casing used for video calls. The captured images are meant to be > - displayed in landscape mode (width > height) on the laptop screen. > - > - The camera is typically mounted upside-down to compensate the lens > - optical inversion effect: > - > - Y-Rp > - Y-Rc ^ > - ^ ! > - ! ! > - ! ! |\_____)\__ > - ! ! ) ____ ___.< > - ! ! |/ )/ > - ! ! > - ! ! > - ! ! > - ! 0 +-------------------------------------> > - ! 0 X-Rp > - 0 +-------------------------------------> > - 0 X-Rc > - > - The two reference systems are aligned, the resulting camera rotation is > - 0 degrees, no rotation correction needs to be applied to the resulting > - image once captured to memory buffers to correctly display it to users: > - > - +--------------------------------------+ > - ! ! > - ! ! > - ! ! > - ! |\____)\___ ! > - ! ) _____ __`< ! > - ! |/ )/ ! > - ! ! > - ! ! > - ! ! > - +--------------------------------------+ > - > - If the camera sensor is not mounted upside-down to compensate for the > - lens optical inversion, the two reference systems will not be aligned, > - with 'Rp' being rotated 180 degrees relatively to 'Rc': > - > - > - X-Rc 0 > - <------------------------------------+ 0 > - ! > - Y-Rp ! > - ^ ! > - ! ! > - ! |\_____)\__ ! > - ! ) ____ ___.< ! > - ! |/ )/ ! > - ! ! > - ! ! > - ! V > - ! Y-Rc > - 0 +-------------------------------------> > - 0 X-Rp > - > - The image once captured to memory will then be rotated by 180 degrees: > - > - +--------------------------------------+ > - ! ! > - ! ! > - ! ! > - ! __/(_____/| ! > - ! >.___ ____ ( ! > - ! \( \| ! > - ! ! > - ! ! > - ! ! > - +--------------------------------------+ > - > - A software rotation correction of 180 degrees should be applied to > - correctly display the image: > - > - +--------------------------------------+ > - ! ! > - ! ! > - ! ! > - ! |\____)\___ ! > - ! ) _____ __`< ! > - ! |/ )/ ! > - ! ! > - ! ! > - ! ! > - +--------------------------------------+ > - > - Example two - Phone camera > - > - A camera installed on the back side of a mobile device facing away from > - the user. The captured images are meant to be displayed in portrait mode > - (height > width) to match the device screen orientation and the device > - usage orientation used when taking the picture. > - > - The camera sensor is typically mounted with its pixel array longer side > - aligned to the device longer side, upside-down mounted to compensate for > - the lens optical inversion effect: > - > - 0 Y-Rc > - 0 +--------------------> > - ! Y-Rp > - ! ^ > - ! ! > - ! ! > - ! ! > - ! ! |\_____)\__ > - ! ! ) ____ ___.< > - ! ! |/ )/ > - ! ! > - ! ! > - ! ! > - ! 0 +-------------------------------------> > - ! 0 X-Rp > - ! > - ! > - ! > - ! > - V > - X-Rc > - > - The two reference systems are not aligned and the 'Rp' reference > - system is rotated by 90 degrees in the counter-clockwise direction > - relatively to the 'Rc' reference system. > - > - The image once captured to memory will be rotated: > - > - +-------------------------------------+ > - | _ _ | > - | \ / | > - | | | | > - | | | | > - | | > | > - | < | | > - | | | | > - | . | > - | V | > - +-------------------------------------+ > - > - A correction of 90 degrees in counter-clockwise direction has to be > - applied to correctly display the image in portrait mode on the device > - screen: > - > - +--------------------+ > - | | > - | | > - | | > - | | > - | | > - | | > - | |\____)\___ | > - | ) _____ __`< | > - | |/ )/ | > - | | > - | | > - | | > - | | > - | | > - +--------------------+ > - > -- orientation: The orientation of a device (typically an image sensor or a flash > - LED) describing its mounting position relative to the usage orientation of the > - system where the device is installed on. > - Possible values are: > - 0 - Front. The device is mounted on the front facing side of the system. > - For mobile devices such as smartphones, tablets and laptops the front side is > - the user facing side. > - 1 - Back. The device is mounted on the back side of the system, which is > - defined as the opposite side of the front facing one. > - 2 - External. The device is not attached directly to the system but is > - attached in a way that allows it to move freely. > - > -Optional endpoint properties > ----------------------------- > - > -- remote-endpoint: phandle to an 'endpoint' subnode of a remote device node. > -- slave-mode: a boolean property indicating that the link is run in slave mode. > - The default when this property is not specified is master mode. In the slave > - mode horizontal and vertical synchronization signals are provided to the > - slave device (data source) by the master device (data sink). In the master > - mode the data source device is also the source of the synchronization signals. > -- bus-type: data bus type. Possible values are: > - 1 - MIPI CSI-2 C-PHY > - 2 - MIPI CSI1 > - 3 - CCP2 > - 4 - MIPI CSI-2 D-PHY > - 5 - Parallel > - 6 - Bt.656 > -- bus-width: number of data lines actively used, valid for the parallel busses. > -- data-shift: on the parallel data busses, if bus-width is used to specify the > - number of data lines, data-shift can be used to specify which data lines are > - used, e.g. "bus-width=<8>; data-shift=<2>;" means, that lines 9:2 are used. > -- hsync-active: active state of the HSYNC signal, 0/1 for LOW/HIGH respectively. > -- vsync-active: active state of the VSYNC signal, 0/1 for LOW/HIGH respectively. > - Note, that if HSYNC and VSYNC polarities are not specified, embedded > - synchronization may be required, where supported. > -- data-active: similar to HSYNC and VSYNC, specifies data line polarity. > -- data-enable-active: similar to HSYNC and VSYNC, specifies the data enable > - signal polarity. > -- field-even-active: field signal level during the even field data transmission. > -- pclk-sample: sample data on rising (1) or falling (0) edge of the pixel clock > - signal. > -- sync-on-green-active: active state of Sync-on-green (SoG) signal, 0/1 for > - LOW/HIGH respectively. > -- data-lanes: an array of physical data lane indexes. Position of an entry > - determines the logical lane number, while the value of an entry indicates > - physical lane, e.g. for 2-lane MIPI CSI-2 bus we could have > - "data-lanes = <1 2>;", assuming the clock lane is on hardware lane 0. > - If the hardware does not support lane reordering, monotonically > - incremented values shall be used from 0 or 1 onwards, depending on > - whether or not there is also a clock lane. This property is valid for > - serial busses only (e.g. MIPI CSI-2). > -- clock-lanes: an array of physical clock lane indexes. Position of an entry > - determines the logical lane number, while the value of an entry indicates > - physical lane, e.g. for a MIPI CSI-2 bus we could have "clock-lanes = <0>;", > - which places the clock lane on hardware lane 0. This property is valid for > - serial busses only (e.g. MIPI CSI-2). Note that for the MIPI CSI-2 bus this > - array contains only one entry. > -- clock-noncontinuous: a boolean property to allow MIPI CSI-2 non-continuous > - clock mode. > -- link-frequencies: Allowed data bus frequencies. For MIPI CSI-2, for > - instance, this is the actual frequency of the bus, not bits per clock per > - lane value. An array of 64-bit unsigned integers. > -- lane-polarities: an array of polarities of the lanes starting from the clock > - lane and followed by the data lanes in the same order as in data-lanes. > - Valid values are 0 (normal) and 1 (inverted). The length of the array > - should be the combined length of data-lanes and clock-lanes properties. > - If the lane-polarities property is omitted, the value must be interpreted > - as 0 (normal). This property is valid for serial busses only. > -- strobe: Whether the clock signal is used as clock (0) or strobe (1). Used > - with CCP2, for instance. > - > -Example > -------- > - > -The example snippet below describes two data pipelines. ov772x and imx074 are > -camera sensors with a parallel and serial (MIPI CSI-2) video bus respectively. > -Both sensors are on the I2C control bus corresponding to the i2c0 controller > -node. ov772x sensor is linked directly to the ceu0 video host interface. > -imx074 is linked to ceu0 through the MIPI CSI-2 receiver (csi2). ceu0 has a > -(single) DMA engine writing captured data to memory. ceu0 node has a single > -'port' node which may indicate that at any time only one of the following data > -pipelines can be active: ov772x -> ceu0 or imx074 -> csi2 -> ceu0. > - > - ceu0: ceu@fe910000 { > - compatible = "renesas,sh-mobile-ceu"; > - reg = <0xfe910000 0xa0>; > - interrupts = <0x880>; > - > - mclk: master_clock { > - compatible = "renesas,ceu-clock"; > - #clock-cells = <1>; > - clock-frequency = <50000000>; /* Max clock frequency */ > - clock-output-names = "mclk"; > - }; > - > - port { > - #address-cells = <1>; > - #size-cells = <0>; > - > - /* Parallel bus endpoint */ > - ceu0_1: endpoint@1 { > - reg = <1>; /* Local endpoint # */ > - remote = <&ov772x_1_1>; /* Remote phandle */ > - bus-width = <8>; /* Used data lines */ > - data-shift = <2>; /* Lines 9:2 are used */ > - > - /* If hsync-active/vsync-active are missing, > - embedded BT.656 sync is used */ > - hsync-active = <0>; /* Active low */ > - vsync-active = <0>; /* Active low */ > - data-active = <1>; /* Active high */ > - pclk-sample = <1>; /* Rising */ > - }; > - > - /* MIPI CSI-2 bus endpoint */ > - ceu0_0: endpoint@0 { > - reg = <0>; > - remote = <&csi2_2>; > - }; > - }; > - }; > - > - i2c0: i2c@fff20000 { > - ... > - ov772x_1: camera@21 { > - compatible = "ovti,ov772x"; > - reg = <0x21>; > - vddio-supply = <®ulator1>; > - vddcore-supply = <®ulator2>; > - > - clock-frequency = <20000000>; > - clocks = <&mclk 0>; > - clock-names = "xclk"; > - > - port { > - /* With 1 endpoint per port no need for addresses. */ > - ov772x_1_1: endpoint { > - bus-width = <8>; > - remote-endpoint = <&ceu0_1>; > - hsync-active = <1>; > - vsync-active = <0>; /* Who came up with an > - inverter here ?... */ > - data-active = <1>; > - pclk-sample = <1>; > - }; > - }; > - }; > - > - imx074: camera@1a { > - compatible = "sony,imx074"; > - reg = <0x1a>; > - vddio-supply = <®ulator1>; > - vddcore-supply = <®ulator2>; > - > - clock-frequency = <30000000>; /* Shared clock with ov772x_1 */ > - clocks = <&mclk 0>; > - clock-names = "sysclk"; /* Assuming this is the > - name in the datasheet */ > - port { > - imx074_1: endpoint { > - clock-lanes = <0>; > - data-lanes = <1 2>; > - remote-endpoint = <&csi2_1>; > - }; > - }; > - }; > - }; > - > - csi2: csi2@ffc90000 { > - compatible = "renesas,sh-mobile-csi2"; > - reg = <0xffc90000 0x1000>; > - interrupts = <0x17a0>; > - #address-cells = <1>; > - #size-cells = <0>; > - > - port@1 { > - compatible = "renesas,csi2c"; /* One of CSI2I and CSI2C. */ > - reg = <1>; /* CSI-2 PHY #1 of 2: PHY_S, > - PHY_M has port address 0, > - is unused. */ > - csi2_1: endpoint { > - clock-lanes = <0>; > - data-lanes = <2 1>; > - remote-endpoint = <&imx074_1>; > - }; > - }; > - port@2 { > - reg = <2>; /* port 2: link to the CEU */ > - > - csi2_2: endpoint { > - remote-endpoint = <&ceu0_0>; > - }; > - }; > - }; > +This file has moved to video-interfaces.yaml and video-interface-devices.yaml. > diff --git a/Documentation/devicetree/bindings/media/video-interfaces.yaml b/Documentation/devicetree/bindings/media/video-interfaces.yaml > new file mode 100644 > index 000000000000..0a7a73fd59f2 > --- /dev/null > +++ b/Documentation/devicetree/bindings/media/video-interfaces.yaml > @@ -0,0 +1,344 @@ > +# SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause) > +%YAML 1.2 > +--- > +$id: http://devicetree.org/schemas/media/video-interfaces.yaml# > +$schema: http://devicetree.org/meta-schemas/core.yaml# > + > +title: Common bindings for video receiver and transmitter interface endpoints > + > +maintainers: > + - Sakari Ailus <sakari.ailus@xxxxxxxxxxxxxxx> > + - Laurent Pinchart <laurent.pinchart@xxxxxxxxxxxxxxxx> > + > +description: | > + Video data pipelines usually consist of external devices, e.g. camera sensors, > + controlled over an I2C, SPI or UART bus, and SoC internal IP blocks, including > + video DMA engines and video data processors. > + > + SoC internal blocks are described by DT nodes, placed similarly to other SoC > + blocks. External devices are represented as child nodes of their respective > + bus controller nodes, e.g. I2C. > + > + Data interfaces on all video devices are described by their child 'port' nodes. > + Configuration of a port depends on other devices participating in the data > + transfer and is described by 'endpoint' subnodes. > + > + device { > + ... > + ports { > + #address-cells = <1>; > + #size-cells = <0>; > + > + port@0 { > + ... > + endpoint@0 { ... }; > + endpoint@1 { ... }; > + }; > + port@1 { ... }; > + }; > + }; > + > + If a port can be configured to work with more than one remote device on the same > + bus, an 'endpoint' child node must be provided for each of them. If more than > + one port is present in a device node or there is more than one endpoint at a > + port, or port node needs to be associated with a selected hardware interface, > + a common scheme using '#address-cells', '#size-cells' and 'reg' properties is > + used. > + > + All 'port' nodes can be grouped under optional 'ports' node, which allows to > + specify #address-cells, #size-cells properties independently for the 'port' > + and 'endpoint' nodes and any child device nodes a device might have. > + > + Two 'endpoint' nodes are linked with each other through their 'remote-endpoint' > + phandles. An endpoint subnode of a device contains all properties needed for > + configuration of this device for data exchange with other device. In most > + cases properties at the peer 'endpoint' nodes will be identical, however they > + might need to be different when there is any signal modifications on the bus > + between two devices, e.g. there are logic signal inverters on the lines. > + > + It is allowed for multiple endpoints at a port to be active simultaneously, > + where supported by a device. For example, in case where a data interface of > + a device is partitioned into multiple data busses, e.g. 16-bit input port > + divided into two separate ITU-R BT.656 8-bit busses. In such case bus-width > + and data-shift properties can be used to assign physical data lines to each > + endpoint node (logical bus). > + > + Documenting bindings for devices > + -------------------------------- > + > + All required and optional bindings the device supports shall be explicitly > + documented in device DT binding documentation. This also includes port and > + endpoint nodes for the device, including unit-addresses and reg properties > + where relevant. > + > +allOf: > + - $ref: /schemas/graph.yaml#/$defs/endpoint-base > + > +properties: > + slave-mode: > + type: boolean > + description: > + Indicates that the link is run in slave mode. The default when this > + property is not specified is master mode. In the slave mode horizontal and > + vertical synchronization signals are provided to the slave device (data > + source) by the master device (data sink). In the master mode the data > + source device is also the source of the synchronization signals. > + > + bus-type: > + $ref: /schemas/types.yaml#/definitions/uint32 > + enum: > + - 1 # MIPI CSI-2 C-PHY > + - 2 # MIPI CSI1 > + - 3 # CCP2 > + - 4 # MIPI CSI-2 D-PHY > + - 5 # Parallel > + - 6 # BT.656 > + description: > + Data bus type. > + > + bus-width: > + $ref: /schemas/types.yaml#/definitions/uint32 > + maximum: 64 > + description: > + Number of data lines actively used, valid for the parallel busses. > + > + data-shift: > + $ref: /schemas/types.yaml#/definitions/uint32 > + maximum: 64 > + description: > + On the parallel data busses, if bus-width is used to specify the number of > + data lines, data-shift can be used to specify which data lines are used, > + e.g. "bus-width=<8>; data-shift=<2>;" means, that lines 9:2 are used. > + > + hsync-active: > + $ref: /schemas/types.yaml#/definitions/uint32 > + enum: [ 0, 1 ] > + description: > + Active state of the HSYNC signal, 0/1 for LOW/HIGH respectively. > + > + vsync-active: > + $ref: /schemas/types.yaml#/definitions/uint32 > + enum: [ 0, 1 ] > + description: > + Active state of the VSYNC signal, 0/1 for LOW/HIGH respectively. Note, > + that if HSYNC and VSYNC polarities are not specified, embedded > + synchronization may be required, where supported. > + > + data-active: > + $ref: /schemas/types.yaml#/definitions/uint32 > + enum: [ 0, 1 ] > + description: > + Similar to HSYNC and VSYNC, specifies data line polarity. > + > + data-enable-active: > + $ref: /schemas/types.yaml#/definitions/uint32 > + enum: [ 0, 1 ] > + description: > + Similar to HSYNC and VSYNC, specifies the data enable signal polarity. > + > + field-even-active: > + $ref: /schemas/types.yaml#/definitions/uint32 > + enum: [ 0, 1 ] > + description: > + Field signal level during the even field data transmission. > + > + pclk-sample: > + $ref: /schemas/types.yaml#/definitions/uint32 > + enum: [ 0, 1 ] > + description: > + Sample data on rising (1) or falling (0) edge of the pixel clock signal. > + > + sync-on-green-active: > + $ref: /schemas/types.yaml#/definitions/uint32 > + enum: [ 0, 1 ] > + description: > + Active state of Sync-on-green (SoG) signal, 0/1 for LOW/HIGH respectively. > + > + data-lanes: > + $ref: /schemas/types.yaml#/definitions/uint32-array > + minItems: 1 > + maxItems: 8 > + items: > + # Assume up to 9 physical lane indices > + maximum: 8 > + description: > + An array of physical data lane indexes. Position of an entry determines > + the logical lane number, while the value of an entry indicates physical > + lane, e.g. for 2-lane MIPI CSI-2 bus we could have "data-lanes = <1 2>;", > + assuming the clock lane is on hardware lane 0. If the hardware does not > + support lane reordering, monotonically incremented values shall be used > + from 0 or 1 onwards, depending on whether or not there is also a clock > + lane. This property is valid for serial busses only (e.g. MIPI CSI-2). > + > + clock-lanes: > + $ref: /schemas/types.yaml#/definitions/uint32 > + # Assume up to 9 physical lane indices > + maximum: 8 > + description: > + Physical clock lane index. Position of an entry determines the logical > + lane number, while the value of an entry indicates physical lane, e.g. for > + a MIPI CSI-2 bus we could have "clock-lanes = <0>;", which places the > + clock lane on hardware lane 0. This property is valid for serial busses > + only (e.g. MIPI CSI-2). > + > + clock-noncontinuous: > + type: boolean > + description: > + Allow MIPI CSI-2 non-continuous clock mode. > + > + link-frequencies: > + $ref: /schemas/types.yaml#/definitions/uint64-array > + description: > + Allowed data bus frequencies. For MIPI CSI-2, for instance, this is the > + actual frequency of the bus, not bits per clock per lane value. An array > + of 64-bit unsigned integers. > + > + lane-polarities: > + $ref: /schemas/types.yaml#/definitions/uint32-array > + minItems: 1 > + maxItems: 9 > + items: > + enum: [ 0, 1 ] > + description: > + An array of polarities of the lanes starting from the clock lane and > + followed by the data lanes in the same order as in data-lanes. Valid > + values are 0 (normal) and 1 (inverted). The length of the array should be > + the combined length of data-lanes and clock-lanes properties. If the > + lane-polarities property is omitted, the value must be interpreted as 0 > + (normal). This property is valid for serial busses only. > + > + strobe: > + $ref: /schemas/types.yaml#/definitions/uint32 > + enum: [ 0, 1 ] > + description: > + Whether the clock signal is used as clock (0) or strobe (1). Used with > + CCP2, for instance. > + > +additionalProperties: true > + > +examples: > + # The example snippet below describes two data pipelines. ov772x and imx074 > + # are camera sensors with a parallel and serial (MIPI CSI-2) video bus > + # respectively. Both sensors are on the I2C control bus corresponding to the > + # i2c0 controller node. ov772x sensor is linked directly to the ceu0 video > + # host interface. imx074 is linked to ceu0 through the MIPI CSI-2 receiver > + # (csi2). ceu0 has a (single) DMA engine writing captured data to memory. > + # ceu0 node has a single 'port' node which may indicate that at any time > + # only one of the following data pipelines can be active: > + # ov772x -> ceu0 or imx074 -> csi2 -> ceu0. > + - | > + ceu@fe910000 { > + compatible = "renesas,sh-mobile-ceu"; > + reg = <0xfe910000 0xa0>; > + interrupts = <0x880>; > + > + mclk: master_clock { > + compatible = "renesas,ceu-clock"; > + #clock-cells = <1>; > + clock-frequency = <50000000>; /* Max clock frequency */ > + clock-output-names = "mclk"; > + }; > + > + port { > + #address-cells = <1>; > + #size-cells = <0>; > + > + /* Parallel bus endpoint */ > + ceu0_1: endpoint@1 { > + reg = <1>; /* Local endpoint # */ > + remote-endpoint = <&ov772x_1_1>; /* Remote phandle */ > + bus-width = <8>; /* Used data lines */ > + data-shift = <2>; /* Lines 9:2 are used */ > + > + /* If hsync-active/vsync-active are missing, > + embedded BT.656 sync is used */ > + hsync-active = <0>; /* Active low */ > + vsync-active = <0>; /* Active low */ > + data-active = <1>; /* Active high */ > + pclk-sample = <1>; /* Rising */ > + }; > + > + /* MIPI CSI-2 bus endpoint */ > + ceu0_0: endpoint@0 { > + reg = <0>; > + remote-endpoint = <&csi2_2>; > + }; > + }; > + }; > + > + i2c { > + #address-cells = <1>; > + #size-cells = <0>; > + > + camera@21 { > + compatible = "ovti,ov772x"; > + reg = <0x21>; > + vddio-supply = <®ulator1>; > + vddcore-supply = <®ulator2>; > + > + clock-frequency = <20000000>; > + clocks = <&mclk 0>; > + clock-names = "xclk"; > + > + port { > + /* With 1 endpoint per port no need for addresses. */ > + ov772x_1_1: endpoint { > + bus-width = <8>; > + remote-endpoint = <&ceu0_1>; > + hsync-active = <1>; > + vsync-active = <0>; /* Who came up with an > + inverter here ?... */ > + data-active = <1>; > + pclk-sample = <1>; > + }; > + }; > + }; > + > + camera@1a { > + compatible = "sony,imx074"; > + reg = <0x1a>; > + vddio-supply = <®ulator1>; > + vddcore-supply = <®ulator2>; > + > + clock-frequency = <30000000>; /* Shared clock with ov772x_1 */ > + clocks = <&mclk 0>; > + clock-names = "sysclk"; /* Assuming this is the > + name in the datasheet */ > + port { > + imx074_1: endpoint { > + clock-lanes = <0>; > + data-lanes = <1 2>; > + remote-endpoint = <&csi2_1>; > + }; > + }; > + }; > + }; > + > + csi2: csi2@ffc90000 { > + compatible = "renesas,sh-mobile-csi2"; > + reg = <0xffc90000 0x1000>; > + interrupts = <0x17a0>; > + #address-cells = <1>; > + #size-cells = <0>; > + > + port@1 { > + compatible = "renesas,csi2c"; /* One of CSI2I and CSI2C. */ > + reg = <1>; /* CSI-2 PHY #1 of 2: PHY_S, > + PHY_M has port address 0, > + is unused. */ > + csi2_1: endpoint { > + clock-lanes = <0>; > + data-lanes = <2 1>; > + remote-endpoint = <&imx074_1>; > + }; > + }; > + port@2 { > + reg = <2>; /* port 2: link to the CEU */ > + > + csi2_2: endpoint { > + remote-endpoint = <&ceu0_0>; > + }; > + }; > + }; > + > +... > -- > 2.27.0 >