linux_dsm_epyc7002/Documentation/devicetree/bindings/regulator/regulator.txt

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Voltage/Current Regulators
Optional properties:
- regulator-name: A string used as a descriptive name for regulator outputs
- regulator-min-microvolt: smallest voltage consumers may set
- regulator-max-microvolt: largest voltage consumers may set
- regulator-microvolt-offset: Offset applied to voltages to compensate for voltage drops
- regulator-min-microamp: smallest current consumers may set
- regulator-max-microamp: largest current consumers may set
- regulator-input-current-limit-microamp: maximum input current regulator allows
- regulator-always-on: boolean, regulator should never be disabled
- regulator-boot-on: bootloader/firmware enabled regulator
- regulator-allow-bypass: allow the regulator to go into bypass mode
- regulator-allow-set-load: allow the regulator performance level to be configured
- <name>-supply: phandle to the parent supply/regulator node
- regulator-ramp-delay: ramp delay for regulator(in uV/us)
For hardware which supports disabling ramp rate, it should be explicitly
initialised to zero (regulator-ramp-delay = <0>) for disabling ramp delay.
- regulator-enable-ramp-delay: The time taken, in microseconds, for the supply
rail to reach the target voltage, plus/minus whatever tolerance the board
design requires. This property describes the total system ramp time
required due to the combination of internal ramping of the regulator itself,
and board design issues such as trace capacitance and load on the supply.
- regulator-settling-time-us: Settling time, in microseconds, for voltage
change if regulator have the constant time for any level voltage change.
This is useful when regulator have exponential voltage change.
- regulator-settling-time-up-us: Settling time, in microseconds, for voltage
increase if the regulator needs a constant time to settle after voltage
increases of any level. This is useful for regulators with exponential
voltage changes.
- regulator-settling-time-down-us: Settling time, in microseconds, for voltage
decrease if the regulator needs a constant time to settle after voltage
decreases of any level. This is useful for regulators with exponential
voltage changes.
- regulator-soft-start: Enable soft start so that voltage ramps slowly
- regulator-state-standby sub-root node for Standby mode
: equivalent with standby Linux sleep state, which provides energy savings
with a relatively quick transition back time.
- regulator-state-mem sub-root node for Suspend-to-RAM mode
: suspend to memory, the device goes to sleep, but all data stored in memory,
only some external interrupt can wake the device.
- regulator-state-disk sub-root node for Suspend-to-DISK mode
: suspend to disk, this state operates similarly to Suspend-to-RAM,
but includes a final step of writing memory contents to disk.
- regulator-state-[mem/disk/standby] node has following common properties:
- regulator-on-in-suspend: regulator should be on in suspend state.
- regulator-off-in-suspend: regulator should be off in suspend state.
- regulator-suspend-min-microvolt: minimum voltage may be set in
suspend state.
- regulator-suspend-max-microvolt: maximum voltage may be set in
suspend state.
- regulator-suspend-microvolt: the default voltage which regulator
would be set in suspend. This property is now deprecated, instead
setting voltage for suspend mode via the API which regulator
driver provides is recommended.
- regulator-changeable-in-suspend: whether the default voltage and
the regulator on/off in suspend can be changed in runtime.
- regulator-mode: operating mode in the given suspend state.
The set of possible operating modes depends on the capabilities of
every hardware so the valid modes are documented on each regulator
device tree binding document.
- regulator-initial-mode: initial operating mode. The set of possible operating
modes depends on the capabilities of every hardware so each device binding
documentation explains which values the regulator supports.
- regulator-allowed-modes: list of operating modes that software is allowed to
configure for the regulator at run-time. Elements may be specified in any
order. The set of possible operating modes depends on the capabilities of
every hardware so each device binding document explains which values the
regulator supports.
- regulator-system-load: Load in uA present on regulator that is not captured by
any consumer request.
- regulator-pull-down: Enable pull down resistor when the regulator is disabled.
- regulator-over-current-protection: Enable over current protection.
- regulator-active-discharge: tristate, enable/disable active discharge of
regulators. The values are:
0: Disable active discharge.
1: Enable active discharge.
Absence of this property will leave configuration to default.
- regulator-coupled-with: Regulators with which the regulator
is coupled. The linkage is 2-way - all coupled regulators should be linked
with each other. A regulator should not be coupled with its supplier.
- regulator-coupled-max-spread: Array of maximum spread between voltages of
coupled regulators in microvolts, each value in the array relates to the
corresponding couple specified by the regulator-coupled-with property.
- regulator-max-step-microvolt: Maximum difference between current and target
voltages that can be changed safely in a single step.
Deprecated properties:
- regulator-compatible: If a regulator chip contains multiple
regulators, and if the chip's binding contains a child node that
describes each regulator, then this property indicates which regulator
this child node is intended to configure. If this property is missing,
the node's name will be used instead.
Example:
xyzreg: regulator@0 {
regulator-min-microvolt = <1000000>;
regulator-max-microvolt = <2500000>;
regulator-always-on;
vin-supply = <&vin>;
regulator-state-mem {
regulator-on-in-suspend;
};
};
Regulator Consumers:
Consumer nodes can reference one or more of its supplies/
regulators using the below bindings.
- <name>-supply: phandle to the regulator node
These are the same bindings that a regulator in the above
example used to reference its own supply, in which case
its just seen as a special case of a regulator being a
consumer itself.
Example of a consumer device node (mmc) referencing two
regulators (twl_reg1 and twl_reg2),
twl_reg1: regulator@0 {
...
...
...
};
twl_reg2: regulator@1 {
...
...
...
};
mmc: mmc@0 {
...
...
vmmc-supply = <&twl_reg1>;
vmmcaux-supply = <&twl_reg2>;
};