mirror of https://gitee.com/openkylin/linux.git
530 lines
14 KiB
Plaintext
530 lines
14 KiB
Plaintext
Generic OPP (Operating Performance Points) Bindings
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----------------------------------------------------
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Devices work at voltage-current-frequency combinations and some implementations
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have the liberty of choosing these. These combinations are called Operating
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Performance Points aka OPPs. This document defines bindings for these OPPs
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applicable across wide range of devices. For illustration purpose, this document
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uses CPU as a device.
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This document contain multiple versions of OPP binding and only one of them
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should be used per device.
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Binding 1: operating-points
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============================
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This binding only supports voltage-frequency pairs.
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Properties:
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- operating-points: An array of 2-tuples items, and each item consists
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of frequency and voltage like <freq-kHz vol-uV>.
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freq: clock frequency in kHz
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vol: voltage in microvolt
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Examples:
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cpu@0 {
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compatible = "arm,cortex-a9";
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reg = <0>;
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next-level-cache = <&L2>;
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operating-points = <
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/* kHz uV */
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792000 1100000
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396000 950000
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198000 850000
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>;
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};
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Binding 2: operating-points-v2
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============================
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* Property: operating-points-v2
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Devices supporting OPPs must set their "operating-points-v2" property with
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phandle to a OPP table in their DT node. The OPP core will use this phandle to
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find the operating points for the device.
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If required, this can be extended for SoC vendor specific bindings. Such bindings
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should be documented as Documentation/devicetree/bindings/power/<vendor>-opp.txt
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and should have a compatible description like: "operating-points-v2-<vendor>".
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* OPP Table Node
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This describes the OPPs belonging to a device. This node can have following
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properties:
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Required properties:
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- compatible: Allow OPPs to express their compatibility. It should be:
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"operating-points-v2".
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- OPP nodes: One or more OPP nodes describing voltage-current-frequency
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combinations. Their name isn't significant but their phandle can be used to
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reference an OPP.
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Optional properties:
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- opp-shared: Indicates that device nodes using this OPP Table Node's phandle
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switch their DVFS state together, i.e. they share clock/voltage/current lines.
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Missing property means devices have independent clock/voltage/current lines,
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but they share OPP tables.
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- status: Marks the OPP table enabled/disabled.
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* OPP Node
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This defines voltage-current-frequency combinations along with other related
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properties.
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Required properties:
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- opp-hz: Frequency in Hz, expressed as a 64-bit big-endian integer.
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Optional properties:
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- opp-microvolt: voltage in micro Volts.
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A single regulator's voltage is specified with an array of size one or three.
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Single entry is for target voltage and three entries are for <target min max>
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voltages.
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Entries for multiple regulators shall be provided in the same field separated
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by angular brackets <>. The OPP binding doesn't provide any provisions to
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relate the values to their power supplies or the order in which the supplies
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need to be configured and that is left for the implementation specific
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binding.
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Entries for all regulators shall be of the same size, i.e. either all use a
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single value or triplets.
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- opp-microvolt-<name>: Named opp-microvolt property. This is exactly similar to
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the above opp-microvolt property, but allows multiple voltage ranges to be
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provided for the same OPP. At runtime, the platform can pick a <name> and
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matching opp-microvolt-<name> property will be enabled for all OPPs. If the
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platform doesn't pick a specific <name> or the <name> doesn't match with any
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opp-microvolt-<name> properties, then opp-microvolt property shall be used, if
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present.
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- opp-microamp: The maximum current drawn by the device in microamperes
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considering system specific parameters (such as transients, process, aging,
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maximum operating temperature range etc.) as necessary. This may be used to
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set the most efficient regulator operating mode.
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Should only be set if opp-microvolt is set for the OPP.
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Entries for multiple regulators shall be provided in the same field separated
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by angular brackets <>. If current values aren't required for a regulator,
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then it shall be filled with 0. If current values aren't required for any of
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the regulators, then this field is not required. The OPP binding doesn't
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provide any provisions to relate the values to their power supplies or the
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order in which the supplies need to be configured and that is left for the
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implementation specific binding.
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- opp-microamp-<name>: Named opp-microamp property. Similar to
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opp-microvolt-<name> property, but for microamp instead.
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- clock-latency-ns: Specifies the maximum possible transition latency (in
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nanoseconds) for switching to this OPP from any other OPP.
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- turbo-mode: Marks the OPP to be used only for turbo modes. Turbo mode is
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available on some platforms, where the device can run over its operating
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frequency for a short duration of time limited by the device's power, current
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and thermal limits.
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- opp-suspend: Marks the OPP to be used during device suspend. Only one OPP in
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the table should have this.
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- opp-supported-hw: This enables us to select only a subset of OPPs from the
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larger OPP table, based on what version of the hardware we are running on. We
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still can't have multiple nodes with the same opp-hz value in OPP table.
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It's a user defined array containing a hierarchy of hardware version numbers,
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supported by the OPP. For example: a platform with hierarchy of three levels
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of versions (A, B and C), this field should be like <X Y Z>, where X
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corresponds to Version hierarchy A, Y corresponds to version hierarchy B and Z
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corresponds to version hierarchy C.
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Each level of hierarchy is represented by a 32 bit value, and so there can be
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only 32 different supported version per hierarchy. i.e. 1 bit per version. A
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value of 0xFFFFFFFF will enable the OPP for all versions for that hierarchy
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level. And a value of 0x00000000 will disable the OPP completely, and so we
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never want that to happen.
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If 32 values aren't sufficient for a version hierarchy, than that version
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hierarchy can be contained in multiple 32 bit values. i.e. <X Y Z1 Z2> in the
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above example, Z1 & Z2 refer to the version hierarchy Z.
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- status: Marks the node enabled/disabled.
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Example 1: Single cluster Dual-core ARM cortex A9, switch DVFS states together.
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/ {
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cpus {
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#address-cells = <1>;
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#size-cells = <0>;
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cpu@0 {
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compatible = "arm,cortex-a9";
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reg = <0>;
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next-level-cache = <&L2>;
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clocks = <&clk_controller 0>;
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clock-names = "cpu";
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cpu-supply = <&cpu_supply0>;
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operating-points-v2 = <&cpu0_opp_table>;
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};
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cpu@1 {
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compatible = "arm,cortex-a9";
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reg = <1>;
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next-level-cache = <&L2>;
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clocks = <&clk_controller 0>;
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clock-names = "cpu";
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cpu-supply = <&cpu_supply0>;
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operating-points-v2 = <&cpu0_opp_table>;
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};
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};
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cpu0_opp_table: opp_table0 {
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compatible = "operating-points-v2";
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opp-shared;
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opp-1000000000 {
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opp-hz = /bits/ 64 <1000000000>;
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opp-microvolt = <975000 970000 985000>;
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opp-microamp = <70000>;
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clock-latency-ns = <300000>;
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opp-suspend;
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};
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opp-1100000000 {
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opp-hz = /bits/ 64 <1100000000>;
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opp-microvolt = <1000000 980000 1010000>;
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opp-microamp = <80000>;
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clock-latency-ns = <310000>;
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};
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opp-1200000000 {
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opp-hz = /bits/ 64 <1200000000>;
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opp-microvolt = <1025000>;
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clock-latency-ns = <290000>;
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turbo-mode;
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};
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};
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};
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Example 2: Single cluster, Quad-core Qualcom-krait, switches DVFS states
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independently.
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/ {
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cpus {
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#address-cells = <1>;
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#size-cells = <0>;
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cpu@0 {
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compatible = "qcom,krait";
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reg = <0>;
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next-level-cache = <&L2>;
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clocks = <&clk_controller 0>;
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clock-names = "cpu";
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cpu-supply = <&cpu_supply0>;
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operating-points-v2 = <&cpu_opp_table>;
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};
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cpu@1 {
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compatible = "qcom,krait";
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reg = <1>;
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next-level-cache = <&L2>;
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clocks = <&clk_controller 1>;
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clock-names = "cpu";
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cpu-supply = <&cpu_supply1>;
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operating-points-v2 = <&cpu_opp_table>;
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};
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cpu@2 {
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compatible = "qcom,krait";
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reg = <2>;
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next-level-cache = <&L2>;
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clocks = <&clk_controller 2>;
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clock-names = "cpu";
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cpu-supply = <&cpu_supply2>;
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operating-points-v2 = <&cpu_opp_table>;
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};
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cpu@3 {
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compatible = "qcom,krait";
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reg = <3>;
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next-level-cache = <&L2>;
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clocks = <&clk_controller 3>;
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clock-names = "cpu";
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cpu-supply = <&cpu_supply3>;
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operating-points-v2 = <&cpu_opp_table>;
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};
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};
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cpu_opp_table: opp_table {
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compatible = "operating-points-v2";
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/*
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* Missing opp-shared property means CPUs switch DVFS states
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* independently.
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*/
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opp-1000000000 {
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opp-hz = /bits/ 64 <1000000000>;
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opp-microvolt = <975000 970000 985000>;
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opp-microamp = <70000>;
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clock-latency-ns = <300000>;
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opp-suspend;
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};
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opp-1100000000 {
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opp-hz = /bits/ 64 <1100000000>;
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opp-microvolt = <1000000 980000 1010000>;
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opp-microamp = <80000>;
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clock-latency-ns = <310000>;
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};
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opp-1200000000 {
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opp-hz = /bits/ 64 <1200000000>;
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opp-microvolt = <1025000>;
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opp-microamp = <90000;
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lock-latency-ns = <290000>;
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turbo-mode;
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};
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};
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};
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Example 3: Dual-cluster, Dual-core per cluster. CPUs within a cluster switch
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DVFS state together.
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/ {
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cpus {
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#address-cells = <1>;
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#size-cells = <0>;
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cpu@0 {
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compatible = "arm,cortex-a7";
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reg = <0>;
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next-level-cache = <&L2>;
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clocks = <&clk_controller 0>;
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clock-names = "cpu";
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cpu-supply = <&cpu_supply0>;
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operating-points-v2 = <&cluster0_opp>;
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};
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cpu@1 {
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compatible = "arm,cortex-a7";
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reg = <1>;
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next-level-cache = <&L2>;
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clocks = <&clk_controller 0>;
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clock-names = "cpu";
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cpu-supply = <&cpu_supply0>;
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operating-points-v2 = <&cluster0_opp>;
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};
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cpu@100 {
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compatible = "arm,cortex-a15";
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reg = <100>;
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next-level-cache = <&L2>;
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clocks = <&clk_controller 1>;
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clock-names = "cpu";
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cpu-supply = <&cpu_supply1>;
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operating-points-v2 = <&cluster1_opp>;
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};
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cpu@101 {
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compatible = "arm,cortex-a15";
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reg = <101>;
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next-level-cache = <&L2>;
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clocks = <&clk_controller 1>;
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clock-names = "cpu";
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cpu-supply = <&cpu_supply1>;
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operating-points-v2 = <&cluster1_opp>;
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};
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};
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cluster0_opp: opp_table0 {
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compatible = "operating-points-v2";
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opp-shared;
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opp-1000000000 {
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opp-hz = /bits/ 64 <1000000000>;
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opp-microvolt = <975000 970000 985000>;
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opp-microamp = <70000>;
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clock-latency-ns = <300000>;
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opp-suspend;
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};
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opp-1100000000 {
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opp-hz = /bits/ 64 <1100000000>;
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opp-microvolt = <1000000 980000 1010000>;
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opp-microamp = <80000>;
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clock-latency-ns = <310000>;
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};
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opp-1200000000 {
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opp-hz = /bits/ 64 <1200000000>;
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opp-microvolt = <1025000>;
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opp-microamp = <90000>;
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clock-latency-ns = <290000>;
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turbo-mode;
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};
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};
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cluster1_opp: opp_table1 {
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compatible = "operating-points-v2";
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opp-shared;
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opp-1300000000 {
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opp-hz = /bits/ 64 <1300000000>;
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opp-microvolt = <1050000 1045000 1055000>;
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opp-microamp = <95000>;
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clock-latency-ns = <400000>;
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opp-suspend;
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};
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opp-1400000000 {
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opp-hz = /bits/ 64 <1400000000>;
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opp-microvolt = <1075000>;
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opp-microamp = <100000>;
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clock-latency-ns = <400000>;
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};
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opp-1500000000 {
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opp-hz = /bits/ 64 <1500000000>;
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opp-microvolt = <1100000 1010000 1110000>;
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opp-microamp = <95000>;
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clock-latency-ns = <400000>;
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turbo-mode;
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};
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};
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};
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Example 4: Handling multiple regulators
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/ {
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cpus {
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cpu@0 {
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compatible = "vendor,cpu-type";
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...
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vcc0-supply = <&cpu_supply0>;
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vcc1-supply = <&cpu_supply1>;
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vcc2-supply = <&cpu_supply2>;
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operating-points-v2 = <&cpu0_opp_table>;
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};
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};
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cpu0_opp_table: opp_table0 {
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compatible = "operating-points-v2";
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opp-shared;
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opp-1000000000 {
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opp-hz = /bits/ 64 <1000000000>;
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opp-microvolt = <970000>, /* Supply 0 */
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<960000>, /* Supply 1 */
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<960000>; /* Supply 2 */
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opp-microamp = <70000>, /* Supply 0 */
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<70000>, /* Supply 1 */
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<70000>; /* Supply 2 */
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clock-latency-ns = <300000>;
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};
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/* OR */
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opp-1000000000 {
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opp-hz = /bits/ 64 <1000000000>;
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opp-microvolt = <975000 970000 985000>, /* Supply 0 */
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<965000 960000 975000>, /* Supply 1 */
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<965000 960000 975000>; /* Supply 2 */
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opp-microamp = <70000>, /* Supply 0 */
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<70000>, /* Supply 1 */
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<70000>; /* Supply 2 */
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clock-latency-ns = <300000>;
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};
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/* OR */
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opp-1000000000 {
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opp-hz = /bits/ 64 <1000000000>;
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opp-microvolt = <975000 970000 985000>, /* Supply 0 */
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<965000 960000 975000>, /* Supply 1 */
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<965000 960000 975000>; /* Supply 2 */
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opp-microamp = <70000>, /* Supply 0 */
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<0>, /* Supply 1 doesn't need this */
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<70000>; /* Supply 2 */
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clock-latency-ns = <300000>;
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};
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};
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};
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Example 5: opp-supported-hw
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(example: three level hierarchy of versions: cuts, substrate and process)
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/ {
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cpus {
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cpu@0 {
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compatible = "arm,cortex-a7";
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...
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cpu-supply = <&cpu_supply>
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operating-points-v2 = <&cpu0_opp_table_slow>;
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};
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};
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opp_table {
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compatible = "operating-points-v2";
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opp-shared;
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opp-600000000 {
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/*
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* Supports all substrate and process versions for 0xF
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* cuts, i.e. only first four cuts.
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*/
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opp-supported-hw = <0xF 0xFFFFFFFF 0xFFFFFFFF>
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opp-hz = /bits/ 64 <600000000>;
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opp-microvolt = <915000 900000 925000>;
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...
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};
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opp-800000000 {
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/*
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* Supports:
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* - cuts: only one, 6th cut (represented by 6th bit).
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* - substrate: supports 16 different substrate versions
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* - process: supports 9 different process versions
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*/
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opp-supported-hw = <0x20 0xff0000ff 0x0000f4f0>
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opp-hz = /bits/ 64 <800000000>;
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opp-microvolt = <915000 900000 925000>;
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...
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};
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};
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};
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Example 6: opp-microvolt-<name>, opp-microamp-<name>:
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(example: device with two possible microvolt ranges: slow and fast)
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/ {
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cpus {
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cpu@0 {
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compatible = "arm,cortex-a7";
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...
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operating-points-v2 = <&cpu0_opp_table>;
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};
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};
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cpu0_opp_table: opp_table0 {
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compatible = "operating-points-v2";
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opp-shared;
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opp-1000000000 {
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opp-hz = /bits/ 64 <1000000000>;
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opp-microvolt-slow = <915000 900000 925000>;
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opp-microvolt-fast = <975000 970000 985000>;
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opp-microamp-slow = <70000>;
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opp-microamp-fast = <71000>;
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};
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opp-1200000000 {
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opp-hz = /bits/ 64 <1200000000>;
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opp-microvolt-slow = <915000 900000 925000>, /* Supply vcc0 */
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<925000 910000 935000>; /* Supply vcc1 */
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opp-microvolt-fast = <975000 970000 985000>, /* Supply vcc0 */
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<965000 960000 975000>; /* Supply vcc1 */
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opp-microamp = <70000>; /* Will be used for both slow/fast */
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};
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};
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};
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