1# SPDX-License-Identifier: GPL-2.0 2%YAML 1.2 3--- 4$id: http://devicetree.org/schemas/opp/allwinner,sun50i-h6-operating-points.yaml# 5$schema: http://devicetree.org/meta-schemas/core.yaml# 6 7title: Allwinner H6 CPU OPP 8 9maintainers: 10 - Chen-Yu Tsai <wens@csie.org> 11 - Maxime Ripard <mripard@kernel.org> 12 13description: | 14 For some SoCs, the CPU frequency subset and voltage value of each 15 OPP varies based on the silicon variant in use. Allwinner Process 16 Voltage Scaling Tables defines the voltage and frequency value based 17 on the speedbin blown in the efuse combination. The 18 sun50i-cpufreq-nvmem driver reads the efuse value from the SoC to 19 provide the OPP framework with required information. 20 21allOf: 22 - $ref: opp-v2-base.yaml# 23 24properties: 25 compatible: 26 const: allwinner,sun50i-h6-operating-points 27 28 nvmem-cells: 29 description: | 30 A phandle pointing to a nvmem-cells node representing the efuse 31 registers that has information about the speedbin that is used 32 to select the right frequency/voltage value pair. Please refer 33 the for nvmem-cells bindings 34 Documentation/devicetree/bindings/nvmem/nvmem.txt and also 35 examples below. 36 37 opp-shared: true 38 39required: 40 - compatible 41 - nvmem-cells 42 43patternProperties: 44 "^opp-[0-9]+$": 45 type: object 46 47 properties: 48 opp-hz: true 49 clock-latency-ns: true 50 51 patternProperties: 52 "^opp-microvolt-speed[0-9]$": true 53 54 required: 55 - opp-hz 56 - opp-microvolt-speed0 57 - opp-microvolt-speed1 58 - opp-microvolt-speed2 59 60 unevaluatedProperties: false 61 62additionalProperties: false 63 64examples: 65 - | 66 cpu_opp_table: opp-table { 67 compatible = "allwinner,sun50i-h6-operating-points"; 68 nvmem-cells = <&speedbin_efuse>; 69 opp-shared; 70 71 opp-480000000 { 72 clock-latency-ns = <244144>; /* 8 32k periods */ 73 opp-hz = /bits/ 64 <480000000>; 74 75 opp-microvolt-speed0 = <880000>; 76 opp-microvolt-speed1 = <820000>; 77 opp-microvolt-speed2 = <800000>; 78 }; 79 80 opp-720000000 { 81 clock-latency-ns = <244144>; /* 8 32k periods */ 82 opp-hz = /bits/ 64 <720000000>; 83 84 opp-microvolt-speed0 = <880000>; 85 opp-microvolt-speed1 = <820000>; 86 opp-microvolt-speed2 = <800000>; 87 }; 88 89 opp-816000000 { 90 clock-latency-ns = <244144>; /* 8 32k periods */ 91 opp-hz = /bits/ 64 <816000000>; 92 93 opp-microvolt-speed0 = <880000>; 94 opp-microvolt-speed1 = <820000>; 95 opp-microvolt-speed2 = <800000>; 96 }; 97 98 opp-888000000 { 99 clock-latency-ns = <244144>; /* 8 32k periods */ 100 opp-hz = /bits/ 64 <888000000>; 101 102 opp-microvolt-speed0 = <940000>; 103 opp-microvolt-speed1 = <820000>; 104 opp-microvolt-speed2 = <800000>; 105 }; 106 107 opp-1080000000 { 108 clock-latency-ns = <244144>; /* 8 32k periods */ 109 opp-hz = /bits/ 64 <1080000000>; 110 111 opp-microvolt-speed0 = <1060000>; 112 opp-microvolt-speed1 = <880000>; 113 opp-microvolt-speed2 = <840000>; 114 }; 115 116 opp-1320000000 { 117 clock-latency-ns = <244144>; /* 8 32k periods */ 118 opp-hz = /bits/ 64 <1320000000>; 119 120 opp-microvolt-speed0 = <1160000>; 121 opp-microvolt-speed1 = <940000>; 122 opp-microvolt-speed2 = <900000>; 123 }; 124 125 opp-1488000000 { 126 clock-latency-ns = <244144>; /* 8 32k periods */ 127 opp-hz = /bits/ 64 <1488000000>; 128 129 opp-microvolt-speed0 = <1160000>; 130 opp-microvolt-speed1 = <1000000>; 131 opp-microvolt-speed2 = <960000>; 132 }; 133 }; 134 135... 136