Documentation/devicetree/bindings/display/mipi-dsi-bus.txt - linux - Git at Google

 MIPI DSI (Display Serial Interface) busses
 ==========================================

 The MIPI Display Serial Interface specifies a serial bus and a protocol for
 communication between a host and up to four peripherals. This document will
 define the syntax used to represent a DSI bus in a device tree.

 This document describes DSI bus-specific properties only or defines existing
 standard properties in the context of the DSI bus.

 Each DSI host provides a DSI bus. The DSI host controller's node contains a
 set of properties that characterize the bus. Child nodes describe individual
 peripherals on that bus.

 The following assumes that only a single peripheral is connected to a DSI
 host. Experience shows that this is true for the large majority of setups.

 DSI host
 ========

 In addition to the standard properties and those defined by the parent bus of
 a DSI host, the following properties apply to a node representing a DSI host.

 Required properties:
 - #address-cells: The number of cells required to represent an address on the
   bus. DSI peripherals are addressed using a 2-bit virtual channel number, so
   a maximum of 4 devices can be addressed on a single bus. Hence the value of
   this property should be 1.
 - #size-cells: Should be 0. There are cases where it makes sense to use a
   different value here. See below.

 Optional properties:
 - clock-master: boolean. Should be enabled if the host is being used in
   conjunction with another DSI host to drive the same peripheral. Hardware
   supporting such a configuration generally requires the data on both the busses
   to be driven by the same clock. Only the DSI host instance controlling this
   clock should contain this property.

 DSI peripheral
 ==============

 Peripherals with DSI as control bus, or no control bus
 ------------------------------------------------------

 Peripherals with the DSI bus as the primary control bus, or peripherals with
 no control bus but use the DSI bus to transmit pixel data are represented
 as child nodes of the DSI host's node. Properties described here apply to all
 DSI peripherals, but individual bindings may want to define additional,
 device-specific properties.

 Required properties:
 - reg: The virtual channel number of a DSI peripheral. Must be in the range
   from 0 to 3.

 Some DSI peripherals respond to more than a single virtual channel. In that
 case two alternative representations can be chosen:
 - The reg property can take multiple entries, one for each virtual channel
   that the peripheral responds to.
 - If the virtual channels that a peripheral responds to are consecutive, the
   #size-cells can be set to 1. The first cell of each entry in the reg
   property is the number of the first virtual channel and the second cell is
   the number of consecutive virtual channels.

 Peripherals with a different control bus
 ----------------------------------------

 There are peripherals that have I2C/SPI (or some other non-DSI bus) as the
 primary control bus, but are also connected to a DSI bus (mostly for the data
 path). Connections between such peripherals and a DSI host can be represented
 using the graph bindings [1], [2].

 Peripherals that support dual channel DSI
 -----------------------------------------

 Peripherals with higher bandwidth requirements can be connected to 2 DSI
 busses. Each DSI bus/channel drives some portion of the pixel data (generally
 left/right half of each line of the display, or even/odd lines of the display).
 The graph bindings should be used to represent the multiple DSI busses that are
 connected to this peripheral. Each DSI host's output endpoint can be linked to
 an input endpoint of the DSI peripheral.

 [1] Documentation/devicetree/bindings/graph.txt
 [2] Documentation/devicetree/bindings/media/video-interfaces.txt

 Examples
 ========
 - (1), (2) and (3) are examples of a DSI host and peripheral on the DSI bus
   with different virtual channel configurations.
 - (4) is an example of a peripheral on a I2C control bus connected to a
   DSI host using of-graph bindings.
 - (5) is an example of 2 DSI hosts driving a dual-channel DSI peripheral,
   which uses I2C as its primary control bus.

 1)
 	dsi-host {
 		...

 		#address-cells = <1>;
 		#size-cells = <0>;

 		/* peripheral responds to virtual channel 0 */
 		peripheral@0 {
 			compatible = "...";
 			reg = <0>;
 		};

 		...
 	};

 2)
 	dsi-host {
 		...

 		#address-cells = <1>;
 		#size-cells = <0>;

 		/* peripheral responds to virtual channels 0 and 2 */
 		peripheral@0 {
 			compatible = "...";
 			reg = <0, 2>;
 		};

 		...
 	};

 3)
 	dsi-host {
 		...

 		#address-cells = <1>;
 		#size-cells = <1>;

 		/* peripheral responds to virtual channels 1, 2 and 3 */
 		peripheral@1 {
 			compatible = "...";
 			reg = <1 3>;
 		};

 		...
 	};

 4)
 	i2c-host {
 		...

 		dsi-bridge@35 {
 			compatible = "...";
 			reg = <0x35>;

 			ports {
 				...

 				port {
 					bridge_mipi_in: endpoint {
 						remote-endpoint = <&host_mipi_out>;
 					};
 				};
 			};
 		};
 	};

 	dsi-host {
 		...

 		ports {
 			...

 			port {
 				host_mipi_out: endpoint {
 					remote-endpoint = <&bridge_mipi_in>;
 				};
 			};
 		};
 	};

 5)
 	i2c-host {
 		dsi-bridge@35 {
 			compatible = "...";
 			reg = <0x35>;

 			ports {
 				#address-cells = <1>;
 				#size-cells = <0>;

 				port@0 {
 					reg = <0>;
 					dsi0_in: endpoint {
 						remote-endpoint = <&dsi0_out>;
 					};
 				};

 				port@1 {
 					reg = <1>;
 					dsi1_in: endpoint {
 						remote-endpoint = <&dsi1_out>;
 					};
 				};
 			};
 		};
 	};

 	dsi0-host {
 		...

 		/*
 		 * this DSI instance drives the clock for both the host
 		 * controllers
 		 */
 		clock-master;

 		ports {
 			...

 			port {
 				dsi0_out: endpoint {
 					remote-endpoint = <&dsi0_in>;
 				};
 			};
 		};
 	};

 	dsi1-host {
 		...

 		ports {
 			...

 			port {
 				dsi1_out: endpoint {
 					remote-endpoint = <&dsi1_in>;
 				};
 			};
 		};
 	};
	MIPI DSI (Display Serial Interface) busses
	==========================================

	The MIPI Display Serial Interface specifies a serial bus and a protocol for
	communication between a host and up to four peripherals. This document will
	define the syntax used to represent a DSI bus in a device tree.

	This document describes DSI bus-specific properties only or defines existing
	standard properties in the context of the DSI bus.

	Each DSI host provides a DSI bus. The DSI host controller's node contains a
	set of properties that characterize the bus. Child nodes describe individual
	peripherals on that bus.

	The following assumes that only a single peripheral is connected to a DSI
	host. Experience shows that this is true for the large majority of setups.

	DSI host
	========

	In addition to the standard properties and those defined by the parent bus of
	a DSI host, the following properties apply to a node representing a DSI host.

	Required properties:
	- #address-cells: The number of cells required to represent an address on the
	bus. DSI peripherals are addressed using a 2-bit virtual channel number, so
	a maximum of 4 devices can be addressed on a single bus. Hence the value of
	this property should be 1.
	- #size-cells: Should be 0. There are cases where it makes sense to use a
	different value here. See below.

	Optional properties:
	- clock-master: boolean. Should be enabled if the host is being used in
	conjunction with another DSI host to drive the same peripheral. Hardware
	supporting such a configuration generally requires the data on both the busses
	to be driven by the same clock. Only the DSI host instance controlling this
	clock should contain this property.

	DSI peripheral
	==============

	Peripherals with DSI as control bus, or no control bus
	------------------------------------------------------

	Peripherals with the DSI bus as the primary control bus, or peripherals with
	no control bus but use the DSI bus to transmit pixel data are represented
	as child nodes of the DSI host's node. Properties described here apply to all
	DSI peripherals, but individual bindings may want to define additional,
	device-specific properties.

	Required properties:
	- reg: The virtual channel number of a DSI peripheral. Must be in the range
	from 0 to 3.

	Some DSI peripherals respond to more than a single virtual channel. In that
	case two alternative representations can be chosen:
	- The reg property can take multiple entries, one for each virtual channel
	that the peripheral responds to.
	- If the virtual channels that a peripheral responds to are consecutive, the
	#size-cells can be set to 1. The first cell of each entry in the reg
	property is the number of the first virtual channel and the second cell is
	the number of consecutive virtual channels.

	Peripherals with a different control bus
	----------------------------------------

	There are peripherals that have I2C/SPI (or some other non-DSI bus) as the
	primary control bus, but are also connected to a DSI bus (mostly for the data
	path). Connections between such peripherals and a DSI host can be represented
	using the graph bindings [1], [2].

	Peripherals that support dual channel DSI
	-----------------------------------------

	Peripherals with higher bandwidth requirements can be connected to 2 DSI
	busses. Each DSI bus/channel drives some portion of the pixel data (generally
	left/right half of each line of the display, or even/odd lines of the display).
	The graph bindings should be used to represent the multiple DSI busses that are
	connected to this peripheral. Each DSI host's output endpoint can be linked to
	an input endpoint of the DSI peripheral.

	[1] Documentation/devicetree/bindings/graph.txt
	[2] Documentation/devicetree/bindings/media/video-interfaces.txt

	Examples
	========
	- (1), (2) and (3) are examples of a DSI host and peripheral on the DSI bus
	with different virtual channel configurations.
	- (4) is an example of a peripheral on a I2C control bus connected to a
	DSI host using of-graph bindings.
	- (5) is an example of 2 DSI hosts driving a dual-channel DSI peripheral,
	which uses I2C as its primary control bus.

	1)
	dsi-host {
	...

	#address-cells = <1>;
	#size-cells = <0>;

	/* peripheral responds to virtual channel 0 */
	peripheral@0 {
	compatible = "...";
	reg = <0>;
	};

	...
	};

	2)
	dsi-host {
	...

	#address-cells = <1>;
	#size-cells = <0>;

	/* peripheral responds to virtual channels 0 and 2 */
	peripheral@0 {
	compatible = "...";
	reg = <0, 2>;
	};

	...
	};

	3)
	dsi-host {
	...

	#address-cells = <1>;
	#size-cells = <1>;

	/* peripheral responds to virtual channels 1, 2 and 3 */
	peripheral@1 {
	compatible = "...";
	reg = <1 3>;
	};

	...
	};

	4)
	i2c-host {
	...

	dsi-bridge@35 {
	compatible = "...";
	reg = <0x35>;

	ports {
	...

	port {
	bridge_mipi_in: endpoint {
	remote-endpoint = <&host_mipi_out>;
	};
	};
	};
	};
	};

	dsi-host {
	...

	ports {
	...

	port {
	host_mipi_out: endpoint {
	remote-endpoint = <&bridge_mipi_in>;
	};
	};
	};
	};

	5)
	i2c-host {
	dsi-bridge@35 {
	compatible = "...";
	reg = <0x35>;

	ports {
	#address-cells = <1>;
	#size-cells = <0>;

	port@0 {
	reg = <0>;
	dsi0_in: endpoint {
	remote-endpoint = <&dsi0_out>;
	};
	};

	port@1 {
	reg = <1>;
	dsi1_in: endpoint {
	remote-endpoint = <&dsi1_out>;
	};
	};
	};
	};
	};

	dsi0-host {
	...

	/*
	* this DSI instance drives the clock for both the host
	* controllers
	*/
	clock-master;

	ports {
	...

	port {
	dsi0_out: endpoint {
	remote-endpoint = <&dsi0_in>;
	};
	};
	};
	};

	dsi1-host {
	...

	ports {
	...

	port {
	dsi1_out: endpoint {
	remote-endpoint = <&dsi1_in>;
	};
	};
	};
	};