xref: /linux/Documentation/devicetree/bindings/media/microchip,csi2dc.yaml (revision 34f7c6e7d4396090692a09789db231e12cb4762b)
1# SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause)
2%YAML 1.2
3---
4$id: http://devicetree.org/schemas/media/microchip,csi2dc.yaml#
5$schema: http://devicetree.org/meta-schemas/core.yaml#
6
7title: Microchip CSI2 Demux Controller (CSI2DC)
8
9maintainers:
10  - Eugen Hristev <eugen.hristev@microchip.com>
11
12description:
13  CSI2DC - Camera Serial Interface 2 Demux Controller
14
15  CSI2DC is a hardware block that receives incoming data from either from an
16  IDI interface or from a parallel bus interface.
17  It filters IDI packets based on their data type and virtual channel
18  identifier, then converts the byte stream to a pixel stream into a cross
19  clock domain towards a parallel interface that can be read by a sensor
20  controller.
21  IDI interface is Synopsys proprietary.
22  CSI2DC can act a simple bypass bridge if the incoming data is coming from
23  a parallel interface.
24
25  CSI2DC provides two pipes, one video pipe and one data pipe. Video pipe
26  is connected at the output to a sensor controller and the data pipe is
27  accessible as a DMA slave port to a DMA controller.
28
29  CSI2DC supports a single 'port' node as a sink port with either Synopsys
30  32-bit IDI interface or a parallel interface.
31
32  CSI2DC supports one 'port' node as source port with parallel interface.
33  This is called video pipe.
34  This port has an 'endpoint' that can be connected to a sink port of another
35  controller (next in pipeline).
36
37  CSI2DC also supports direct access to the data through AHB, via DMA channel,
38  called data pipe.
39  For data pipe to be available, a dma controller and a dma channel must be
40  referenced.
41
42properties:
43  compatible:
44    const: microchip,sama7g5-csi2dc
45
46  reg:
47    maxItems: 1
48
49  clocks:
50    minItems: 2
51    maxItems: 2
52
53  clock-names:
54    description:
55      CSI2DC must have two clocks to function correctly. One clock is the
56      peripheral clock for the inside functionality of the hardware block.
57      This is named 'pclk'. The second clock must be the cross domain clock,
58      in which CSI2DC will perform clock crossing. This clock must be fed
59      by the next controller in pipeline, which usually is a sensor controller.
60      Normally this clock should be given by this sensor controller who
61      is also a clock source. This clock is named 'scck', sensor controller clock.
62    items:
63      - const: pclk
64      - const: scck
65
66  dmas:
67    maxItems: 1
68
69  dma-names:
70    const: rx
71
72  ports:
73    $ref: /schemas/graph.yaml#/properties/ports
74
75    properties:
76      port@0:
77        $ref: /schemas/graph.yaml#/$defs/port-base
78        description:
79          Input port node, single endpoint describing the input port.
80
81        properties:
82          endpoint:
83            $ref: video-interfaces.yaml#
84            unevaluatedProperties: false
85            description: Endpoint connected to input device
86
87            properties:
88              bus-type:
89                enum: [4, 5, 6]
90                default: 4
91
92              bus-width:
93                enum: [8, 9, 10, 11, 12, 13, 14]
94                default: 14
95
96              clock-noncontinuous:
97                type: boolean
98                description:
99                  Presence of this boolean property decides whether clock is
100                  continuous or noncontinuous.
101
102              remote-endpoint: true
103
104      port@1:
105        $ref: /schemas/graph.yaml#/$defs/port-base
106        description:
107          Output port node, single endpoint describing the output port.
108
109        properties:
110          endpoint:
111            unevaluatedProperties: false
112            $ref: video-interfaces.yaml#
113            description: Endpoint connected to output device
114
115            properties:
116              bus-type:
117                enum: [5, 6]
118                default: 5
119
120              bus-width:
121                enum: [8, 9, 10, 11, 12, 13, 14]
122                default: 14
123
124              remote-endpoint: true
125
126    required:
127      - port@0
128      - port@1
129
130additionalProperties: false
131
132required:
133  - compatible
134  - reg
135  - clocks
136  - clock-names
137  - ports
138
139examples:
140  # Example for connecting to a parallel sensor controller block (video pipe)
141  # and the input is received from Synopsys IDI interface
142  - |
143    csi2dc@e1404000 {
144        compatible = "microchip,sama7g5-csi2dc";
145        reg = <0xe1404000 0x500>;
146        clocks = <&pclk>, <&scck>;
147        clock-names = "pclk", "scck";
148
149        ports {
150               #address-cells = <1>;
151               #size-cells = <0>;
152               port@0 {
153                       reg = <0>; /* must be 0, first child port */
154                       csi2dc_in: endpoint { /* input from IDI interface */
155                               bus-type = <4>; /* MIPI CSI2 D-PHY */
156                               remote-endpoint = <&csi2host_out>;
157                       };
158               };
159
160               port@1 {
161                       reg = <1>; /* must be 1, second child port */
162                       csi2dc_out: endpoint {
163                               remote-endpoint = <&xisc_in>; /* output to sensor controller */
164                       };
165               };
166        };
167    };
168
169  # Example for connecting to a DMA master as an AHB slave
170  # and the input is received from Synopsys IDI interface
171  - |
172    #include <dt-bindings/dma/at91.h>
173    csi2dc@e1404000 {
174        compatible = "microchip,sama7g5-csi2dc";
175        reg = <0xe1404000 0x500>;
176        clocks = <&pclk>, <&scck>;
177        clock-names = "pclk", "scck";
178        dmas = <&dma0 AT91_XDMAC_DT_PERID(34)>;
179        dma-names = "rx";
180
181        ports {
182               #address-cells = <1>;
183               #size-cells = <0>;
184               port@0 {
185                       reg = <0>; /* must be 0, first child port */
186                       csi2dc_input: endpoint { /* input from IDI interface */
187                               remote-endpoint = <&csi2host_out>;
188                       };
189               };
190
191               port@1 {
192                       reg = <1>;
193               };
194        };
195    };
196
197...
198