Documentation/devicetree/bindings/arm/msm/qcom,idle-state.txt - third_party/linux - Git at Google

 QCOM Idle States for cpuidle driver

 ARM provides idle-state node to define the cpuidle states, as defined in [1].
 cpuidle-qcom is the cpuidle driver for Qualcomm SoCs and uses these idle
 states. Idle states have different enter/exit latency and residency values.
 The idle states supported by the QCOM SoC are defined as -

     * Standby
     * Retention
     * Standalone Power Collapse (Standalone PC or SPC)
     * Power Collapse (PC)

 Standby: Standby does a little more in addition to architectural clock gating.
 When the WFI instruction is executed the ARM core would gate its internal
 clocks. In addition to gating the clocks, QCOM cpus use this instruction as a
 trigger to execute the SPM state machine. The SPM state machine waits for the
 interrupt to trigger the core back in to active. This triggers the cache
 hierarchy to enter standby states, when all cpus are idle. An interrupt brings
 the SPM state machine out of its wait, the next step is to ensure that the
 cache hierarchy is also out of standby, and then the cpu is allowed to resume
 execution. This state is defined as a generic ARM WFI state by the ARM cpuidle
 driver and is not defined in the DT. The SPM state machine should be
 configured to execute this state by default and after executing every other
 state below.

 Retention: Retention is a low power state where the core is clock gated and
 the memory and the registers associated with the core are retained. The
 voltage may be reduced to the minimum value needed to keep the processor
 registers active. The SPM should be configured to execute the retention
 sequence and would wait for interrupt, before restoring the cpu to execution
 state. Retention may have a slightly higher latency than Standby.

 Standalone PC: A cpu can power down and warmboot if there is a sufficient time
 between the time it enters idle and the next known wake up. SPC mode is used
 to indicate a core entering a power down state without consulting any other
 cpu or the system resources. This helps save power only on that core.  The SPM
 sequence for this idle state is programmed to power down the supply to the
 core, wait for the interrupt, restore power to the core, and ensure the
 system state including cache hierarchy is ready before allowing core to
 resume. Applying power and resetting the core causes the core to warmboot
 back into Elevation Level (EL) which trampolines the control back to the
 kernel. Entering a power down state for the cpu, needs to be done by trapping
 into a EL. Failing to do so, would result in a crash enforced by the warm boot
 code in the EL for the SoC. On SoCs with write-back L1 cache, the cache has to
 be flushed in s/w, before powering down the core.

 Power Collapse: This state is similar to the SPC mode, but distinguishes
 itself in that the cpu acknowledges and permits the SoC to enter deeper sleep
 modes. In a hierarchical power domain SoC, this means L2 and other caches can
 be flushed, system bus, clocks - lowered, and SoC main XO clock gated and
 voltages reduced, provided all cpus enter this state.  Since the span of low
 power modes possible at this state is vast, the exit latency and the residency
 of this low power mode would be considered high even though at a cpu level,
 this essentially is cpu power down. The SPM in this state also may handshake
 with the Resource power manager (RPM) processor in the SoC to indicate a
 complete application processor subsystem shut down.

 The idle-state for QCOM SoCs are distinguished by the compatible property of
 the idle-states device node.

 The devicetree representation of the idle state should be -

 Required properties:

 - compatible: Must be one of -
 			"qcom,idle-state-ret",
 			"qcom,idle-state-spc",
 			"qcom,idle-state-pc",
 		and "arm,idle-state".

 Other required and optional properties are specified in [1].

 Example:

 	idle-states {
 		CPU_SPC: spc {
 			compatible = "qcom,idle-state-spc", "arm,idle-state";
 			entry-latency-us = <150>;
 			exit-latency-us = <200>;
 			min-residency-us = <2000>;
 		};
 	};

 [1]. Documentation/devicetree/bindings/arm/idle-states.txt
	QCOM Idle States for cpuidle driver

	ARM provides idle-state node to define the cpuidle states, as defined in [1].
	cpuidle-qcom is the cpuidle driver for Qualcomm SoCs and uses these idle
	states. Idle states have different enter/exit latency and residency values.
	The idle states supported by the QCOM SoC are defined as -

	* Standby
	* Retention
	* Standalone Power Collapse (Standalone PC or SPC)
	* Power Collapse (PC)

	Standby: Standby does a little more in addition to architectural clock gating.
	When the WFI instruction is executed the ARM core would gate its internal
	clocks. In addition to gating the clocks, QCOM cpus use this instruction as a
	trigger to execute the SPM state machine. The SPM state machine waits for the
	interrupt to trigger the core back in to active. This triggers the cache
	hierarchy to enter standby states, when all cpus are idle. An interrupt brings
	the SPM state machine out of its wait, the next step is to ensure that the
	cache hierarchy is also out of standby, and then the cpu is allowed to resume
	execution. This state is defined as a generic ARM WFI state by the ARM cpuidle
	driver and is not defined in the DT. The SPM state machine should be
	configured to execute this state by default and after executing every other
	state below.

	Retention: Retention is a low power state where the core is clock gated and
	the memory and the registers associated with the core are retained. The
	voltage may be reduced to the minimum value needed to keep the processor
	registers active. The SPM should be configured to execute the retention
	sequence and would wait for interrupt, before restoring the cpu to execution
	state. Retention may have a slightly higher latency than Standby.

	Standalone PC: A cpu can power down and warmboot if there is a sufficient time
	between the time it enters idle and the next known wake up. SPC mode is used
	to indicate a core entering a power down state without consulting any other
	cpu or the system resources. This helps save power only on that core. The SPM
	sequence for this idle state is programmed to power down the supply to the
	core, wait for the interrupt, restore power to the core, and ensure the
	system state including cache hierarchy is ready before allowing core to
	resume. Applying power and resetting the core causes the core to warmboot
	back into Elevation Level (EL) which trampolines the control back to the
	kernel. Entering a power down state for the cpu, needs to be done by trapping
	into a EL. Failing to do so, would result in a crash enforced by the warm boot
	code in the EL for the SoC. On SoCs with write-back L1 cache, the cache has to
	be flushed in s/w, before powering down the core.

	Power Collapse: This state is similar to the SPC mode, but distinguishes
	itself in that the cpu acknowledges and permits the SoC to enter deeper sleep
	modes. In a hierarchical power domain SoC, this means L2 and other caches can
	be flushed, system bus, clocks - lowered, and SoC main XO clock gated and
	voltages reduced, provided all cpus enter this state. Since the span of low
	power modes possible at this state is vast, the exit latency and the residency
	of this low power mode would be considered high even though at a cpu level,
	this essentially is cpu power down. The SPM in this state also may handshake
	with the Resource power manager (RPM) processor in the SoC to indicate a
	complete application processor subsystem shut down.

	The idle-state for QCOM SoCs are distinguished by the compatible property of
	the idle-states device node.

	The devicetree representation of the idle state should be -

	Required properties:

	- compatible: Must be one of -
	"qcom,idle-state-ret",
	"qcom,idle-state-spc",
	"qcom,idle-state-pc",
	and "arm,idle-state".

	Other required and optional properties are specified in [1].

	Example:

	idle-states {
	CPU_SPC: spc {
	compatible = "qcom,idle-state-spc", "arm,idle-state";
	entry-latency-us = <150>;
	exit-latency-us = <200>;
	min-residency-us = <2000>;
	};
	};

	[1]. Documentation/devicetree/bindings/arm/idle-states.txt