Commit 41f42b6e authored by Rob Herring's avatar Rob Herring Committed by Mauro Carvalho Chehab

media: dt-bindings: Convert video-interfaces.txt properties to schemas

Convert video-interfaces.txt to DT schema. As it contains a mixture of
device level and endpoint properties, split it up into 2 schemas.

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: default avatarSakari Ailus <sakari.ailus@linux.intel.com>
Acked-by: default avatarJacopo Mondi <jacopo@jmondi.org>
Acked-by: default avatarGuennadi Liakhovetski <g.liakhovetski@gmx.de>
Acked-by: default avatarHans Verkuil <hverkuil-cisco@xs4all.nl>
Reviewed-by: default avatarLaurent Pinchart <laurent.pinchart@ideasonboard.com>
Signed-off-by: default avatarRob Herring <robh@kernel.org>
Signed-off-by: default avatarMauro Carvalho Chehab <mchehab+huawei@kernel.org>
parent 321af22a
# 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@jmondi.org>
- Sakari Ailus <sakari.ailus@linux.intel.com>
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
...
Common bindings for video receiver and transmitter interfaces This file has moved to video-interfaces.yaml and video-interface-devices.yaml.
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 = <&regulator1>;
vddcore-supply = <&regulator2>;
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 = <&regulator1>;
vddcore-supply = <&regulator2>;
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>;
};
};
};
# 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@linux.intel.com>
- Laurent Pinchart <laurent.pinchart@ideasonboard.com>
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 = <&regulator1>;
vddcore-supply = <&regulator2>;
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 = <&regulator1>;
vddcore-supply = <&regulator2>;
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>;
};
};
};
...
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