# SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause) %YAML 1.2 --- $id: http://devicetree.org/schemas/cpu/idle-states.yaml# $schema: http://devicetree.org/meta-schemas/core.yaml# title: Idle states maintainers: - Lorenzo Pieralisi - Anup Patel description: |+ ========================================== 1 - Introduction ========================================== ARM and RISC-V systems contain HW capable of managing power consumption dynamically, where cores can be put in different low-power states (ranging from simple wfi to power gating) according to OS PM policies. The CPU states representing the range of dynamic idle states that a processor can enter at run-time, can be specified through device tree bindings representing the parameters required to enter/exit specific idle states on a given processor. ========================================== 2 - ARM idle states ========================================== According to the Server Base System Architecture document (SBSA, [3]), the power states an ARM CPU can be put into are identified by the following list: - Running - Idle_standby - Idle_retention - Sleep - Off The power states described in the SBSA document define the basic CPU states on top of which ARM platforms implement power management schemes that allow an OS PM implementation to put the processor in different idle states (which include states listed above; "off" state is not an idle state since it does not have wake-up capabilities, hence it is not considered in this document). Idle state parameters (e.g. entry latency) are platform specific and need to be characterized with bindings that provide the required information to OS PM code so that it can build the required tables and use them at runtime. The device tree binding definition for ARM idle states is the subject of this document. ========================================== 3 - RISC-V idle states ========================================== On RISC-V systems, the HARTs (or CPUs) [6] can be put in platform specific suspend (or idle) states (ranging from simple WFI, power gating, etc). The RISC-V SBI v0.3 (or higher) [7] hart state management extension provides a standard mechanism for OS to request HART state transitions. The platform specific suspend (or idle) states of a hart can be either retentive or non-rententive in nature. A retentive suspend state will preserve HART registers and CSR values for all privilege modes whereas a non-retentive suspend state will not preserve HART registers and CSR values. =========================================== 4 - idle-states definitions =========================================== Idle states are characterized for a specific system through a set of timing and energy related properties, that underline the HW behaviour triggered upon idle states entry and exit. The following diagram depicts the CPU execution phases and related timing properties required to enter and exit an idle state: ..__[EXEC]__|__[PREP]__|__[ENTRY]__|__[IDLE]__|__[EXIT]__|__[EXEC]__.. | | | | | |<------ entry ------->| | latency | |<- exit ->| | latency | |<-------- min-residency -------->| |<------- wakeup-latency ------->| Diagram 1: CPU idle state execution phases EXEC: Normal CPU execution. PREP: Preparation phase before committing the hardware to idle mode like cache flushing. This is abortable on pending wake-up event conditions. The abort latency is assumed to be negligible (i.e. less than the ENTRY + EXIT duration). If aborted, CPU goes back to EXEC. This phase is optional. If not abortable, this should be included in the ENTRY phase instead. ENTRY: The hardware is committed to idle mode. This period must run to completion up to IDLE before anything else can happen. IDLE: This is the actual energy-saving idle period. This may last between 0 and infinite time, until a wake-up event occurs. EXIT: Period during which the CPU is brought back to operational mode (EXEC). entry-latency: Worst case latency required to enter the idle state. The exit-latency may be guaranteed only after entry-latency has passed. min-residency: Minimum period, including preparation and entry, for a given idle state to be worthwhile energywise. wakeup-latency: Maximum delay between the signaling of a wake-up event and the CPU being able to execute normal code again. If not specified, this is assumed to be entry-latency + exit-latency. These timing parameters can be used by an OS in different circumstances. An idle CPU requires the expected min-residency time to select the most appropriate idle state based on the expected expiry time of the next IRQ (i.e. wake-up) that causes the CPU to return to the EXEC phase. An operating system scheduler may need to compute the shortest wake-up delay for CPUs in the system by detecting how long will it take to get a CPU out of an idle state, e.g.: wakeup-delay = exit-latency + max(entry-latency - (now - entry-timestamp), 0) In other words, the scheduler can make its scheduling decision by selecting (e.g. waking-up) the CPU with the shortest wake-up delay. The wake-up delay must take into account the entry latency if that period has not expired. The abortable nature of the PREP period can be ignored if it cannot be relied upon (e.g. the PREP deadline may occur much sooner than the worst case since it depends on the CPU operating conditions, i.e. caches state). An OS has to reliably probe the wakeup-latency since some devices can enforce latency constraint guarantees to work properly, so the OS has to detect the worst case wake-up latency it can incur if a CPU is allowed to enter an idle state, and possibly to prevent that to guarantee reliable device functioning. The min-residency time parameter deserves further explanation since it is expressed in time units but must factor in energy consumption coefficients. The energy consumption of a cpu when it enters a power state can be roughly characterised by the following graph: | | | e | n | /--- e | /------ r | /------ g | /----- y | /------ | ---- | /| | / | | / | | / | | / | | / | |/ | -----|-------+---------------------------------- 0| 1 time(ms) Graph 1: Energy vs time example The graph is split in two parts delimited by time 1ms on the X-axis. The graph curve with X-axis values = { x | 0 < x < 1ms } has a steep slope and denotes the energy costs incurred while entering and leaving the idle state. The graph curve in the area delimited by X-axis values = {x | x > 1ms } has shallower slope and essentially represents the energy consumption of the idle state. min-residency is defined for a given idle state as the minimum expected residency time for a state (inclusive of preparation and entry) after which choosing that state become the most energy efficient option. A good way to visualise this, is by taking the same graph above and comparing some states energy consumptions plots. For sake of simplicity, let's consider a system with two idle states IDLE1, and IDLE2: | | | | /-- IDLE1 e | /--- n | /---- e | /--- r | /-----/--------- IDLE2 g | /-------/--------- y | ------------ /---| | / /---- | | / /--- | | / /---- | | / /--- | | --- | | / | | / | |/ | time ---/----------------------------+------------------------ |IDLE1-energy < IDLE2-energy | IDLE2-energy < IDLE1-energy | IDLE2-min-residency Graph 2: idle states min-residency example In graph 2 above, that takes into account idle states entry/exit energy costs, it is clear that if the idle state residency time (i.e. time till next wake-up IRQ) is less than IDLE2-min-residency, IDLE1 is the better idle state choice energywise. This is mainly down to the fact that IDLE1 entry/exit energy costs are lower than IDLE2. However, the lower power consumption (i.e. shallower energy curve slope) of idle state IDLE2 implies that after a suitable time, IDLE2 becomes more energy efficient. The time at which IDLE2 becomes more energy efficient than IDLE1 (and other shallower states in a system with multiple idle states) is defined IDLE2-min-residency and corresponds to the time when energy consumption of IDLE1 and IDLE2 states breaks even. The definitions provided in this section underpin the idle states properties specification that is the subject of the following sections. =========================================== 5 - idle-states node =========================================== The processor idle states are defined within the idle-states node, which is a direct child of the cpus node [1] and provides a container where the processor idle states, defined as device tree nodes, are listed. On ARM systems, it is a container of processor idle states nodes. If the system does not provide CPU power management capabilities, or the processor just supports idle_standby, an idle-states node is not required. =========================================== 6 - Qualcomm specific 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. =========================================== 7 - References =========================================== [1] ARM Linux Kernel documentation - CPUs bindings Documentation/devicetree/bindings/arm/cpus.yaml [2] ARM Linux Kernel documentation - PSCI bindings Documentation/devicetree/bindings/arm/psci.yaml [3] ARM Server Base System Architecture (SBSA) http://infocenter.arm.com/help/index.jsp [4] ARM Architecture Reference Manuals http://infocenter.arm.com/help/index.jsp [5] ARM Linux Kernel documentation - Booting AArch64 Linux Documentation/arch/arm64/booting.rst [6] RISC-V Linux Kernel documentation - CPUs bindings Documentation/devicetree/bindings/riscv/cpus.yaml [7] RISC-V Supervisor Binary Interface (SBI) http://github.com/riscv/riscv-sbi-doc/riscv-sbi.adoc properties: $nodename: const: idle-states entry-method: description: | Usage and definition depend on ARM architecture version. On ARM v8 64-bit this property is required. On ARM 32-bit systems this property is optional This assumes that the "enable-method" property is set to "psci" in the cpu node[5] that is responsible for setting up CPU idle management in the OS implementation. const: psci patternProperties: "^(cpu|cluster)-": type: object description: | Each state node represents an idle state description and must be defined as follows. The idle state entered by executing the wfi instruction (idle_standby SBSA,[3][4]) is considered standard on all ARM and RISC-V platforms and therefore must not be listed. In addition to the properties listed above, a state node may require additional properties specific to the entry-method defined in the idle-states node. Please refer to the entry-method bindings documentation for properties definitions. properties: compatible: oneOf: - items: - enum: - qcom,idle-state-ret - qcom,idle-state-spc - qcom,idle-state-pc - const: arm,idle-state - enum: - arm,idle-state - riscv,idle-state arm,psci-suspend-param: $ref: /schemas/types.yaml#/definitions/uint32 description: | power_state parameter to pass to the ARM PSCI suspend call. Device tree nodes that require usage of PSCI CPU_SUSPEND function (i.e. idle states node with entry-method property is set to "psci") must specify this property. riscv,sbi-suspend-param: $ref: /schemas/types.yaml#/definitions/uint32 description: | suspend_type parameter to pass to the RISC-V SBI HSM suspend call. This property is required in idle state nodes of device tree meant for RISC-V systems. For more details on the suspend_type parameter refer the SBI specification v0.3 (or higher) [7]. local-timer-stop: description: If present the CPU local timer control logic is lost on state entry, otherwise it is retained. type: boolean entry-latency-us: description: Worst case latency in microseconds required to enter the idle state. exit-latency-us: description: Worst case latency in microseconds required to exit the idle state. The exit-latency-us duration may be guaranteed only after entry-latency-us has passed. min-residency-us: description: Minimum residency duration in microseconds, inclusive of preparation and entry, for this idle state to be considered worthwhile energy wise (refer to section 2 of this document for a complete description). wakeup-latency-us: description: | Maximum delay between the signaling of a wake-up event and the CPU being able to execute normal code again. If omitted, this is assumed to be equal to: entry-latency-us + exit-latency-us It is important to supply this value on systems where the duration of PREP phase (see diagram 1, section 2) is non-neglibigle. In such systems entry-latency-us + exit-latency-us will exceed wakeup-latency-us by this duration. idle-state-name: $ref: /schemas/types.yaml#/definitions/string description: A string used as a descriptive name for the idle state. additionalProperties: false required: - compatible - entry-latency-us - exit-latency-us - min-residency-us additionalProperties: false examples: - | cpus { #size-cells = <0>; #address-cells = <2>; cpu@0 { device_type = "cpu"; compatible = "arm,cortex-a57"; reg = <0x0 0x0>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_0_0>, <&CPU_SLEEP_0_0>, <&CLUSTER_RETENTION_0>, <&CLUSTER_SLEEP_0>; }; cpu@1 { device_type = "cpu"; compatible = "arm,cortex-a57"; reg = <0x0 0x1>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_0_0>, <&CPU_SLEEP_0_0>, <&CLUSTER_RETENTION_0>, <&CLUSTER_SLEEP_0>; }; cpu@100 { device_type = "cpu"; compatible = "arm,cortex-a57"; reg = <0x0 0x100>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_0_0>, <&CPU_SLEEP_0_0>, <&CLUSTER_RETENTION_0>, <&CLUSTER_SLEEP_0>; }; cpu@101 { device_type = "cpu"; compatible = "arm,cortex-a57"; reg = <0x0 0x101>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_0_0>, <&CPU_SLEEP_0_0>, <&CLUSTER_RETENTION_0>, <&CLUSTER_SLEEP_0>; }; cpu@10000 { device_type = "cpu"; compatible = "arm,cortex-a57"; reg = <0x0 0x10000>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_0_0>, <&CPU_SLEEP_0_0>, <&CLUSTER_RETENTION_0>, <&CLUSTER_SLEEP_0>; }; cpu@10001 { device_type = "cpu"; compatible = "arm,cortex-a57"; reg = <0x0 0x10001>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_0_0>, <&CPU_SLEEP_0_0>, <&CLUSTER_RETENTION_0>, <&CLUSTER_SLEEP_0>; }; cpu@10100 { device_type = "cpu"; compatible = "arm,cortex-a57"; reg = <0x0 0x10100>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_0_0>, <&CPU_SLEEP_0_0>, <&CLUSTER_RETENTION_0>, <&CLUSTER_SLEEP_0>; }; cpu@10101 { device_type = "cpu"; compatible = "arm,cortex-a57"; reg = <0x0 0x10101>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_0_0>, <&CPU_SLEEP_0_0>, <&CLUSTER_RETENTION_0>, <&CLUSTER_SLEEP_0>; }; cpu@100000000 { device_type = "cpu"; compatible = "arm,cortex-a53"; reg = <0x1 0x0>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_1_0>, <&CPU_SLEEP_1_0>, <&CLUSTER_RETENTION_1>, <&CLUSTER_SLEEP_1>; }; cpu@100000001 { device_type = "cpu"; compatible = "arm,cortex-a53"; reg = <0x1 0x1>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_1_0>, <&CPU_SLEEP_1_0>, <&CLUSTER_RETENTION_1>, <&CLUSTER_SLEEP_1>; }; cpu@100000100 { device_type = "cpu"; compatible = "arm,cortex-a53"; reg = <0x1 0x100>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_1_0>, <&CPU_SLEEP_1_0>, <&CLUSTER_RETENTION_1>, <&CLUSTER_SLEEP_1>; }; cpu@100000101 { device_type = "cpu"; compatible = "arm,cortex-a53"; reg = <0x1 0x101>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_1_0>, <&CPU_SLEEP_1_0>, <&CLUSTER_RETENTION_1>, <&CLUSTER_SLEEP_1>; }; cpu@100010000 { device_type = "cpu"; compatible = "arm,cortex-a53"; reg = <0x1 0x10000>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_1_0>, <&CPU_SLEEP_1_0>, <&CLUSTER_RETENTION_1>, <&CLUSTER_SLEEP_1>; }; cpu@100010001 { device_type = "cpu"; compatible = "arm,cortex-a53"; reg = <0x1 0x10001>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_1_0>, <&CPU_SLEEP_1_0>, <&CLUSTER_RETENTION_1>, <&CLUSTER_SLEEP_1>; }; cpu@100010100 { device_type = "cpu"; compatible = "arm,cortex-a53"; reg = <0x1 0x10100>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_1_0>, <&CPU_SLEEP_1_0>, <&CLUSTER_RETENTION_1>, <&CLUSTER_SLEEP_1>; }; cpu@100010101 { device_type = "cpu"; compatible = "arm,cortex-a53"; reg = <0x1 0x10101>; enable-method = "psci"; cpu-idle-states = <&CPU_RETENTION_1_0>, <&CPU_SLEEP_1_0>, <&CLUSTER_RETENTION_1>, <&CLUSTER_SLEEP_1>; }; idle-states { entry-method = "psci"; CPU_RETENTION_0_0: cpu-retention-0-0 { compatible = "arm,idle-state"; arm,psci-suspend-param = <0x0010000>; entry-latency-us = <20>; exit-latency-us = <40>; min-residency-us = <80>; }; CLUSTER_RETENTION_0: cluster-retention-0 { compatible = "arm,idle-state"; local-timer-stop; arm,psci-suspend-param = <0x1010000>; entry-latency-us = <50>; exit-latency-us = <100>; min-residency-us = <250>; wakeup-latency-us = <130>; }; CPU_SLEEP_0_0: cpu-sleep-0-0 { compatible = "arm,idle-state"; local-timer-stop; arm,psci-suspend-param = <0x0010000>; entry-latency-us = <250>; exit-latency-us = <500>; min-residency-us = <950>; }; CLUSTER_SLEEP_0: cluster-sleep-0 { compatible = "arm,idle-state"; local-timer-stop; arm,psci-suspend-param = <0x1010000>; entry-latency-us = <600>; exit-latency-us = <1100>; min-residency-us = <2700>; wakeup-latency-us = <1500>; }; CPU_RETENTION_1_0: cpu-retention-1-0 { compatible = "arm,idle-state"; arm,psci-suspend-param = <0x0010000>; entry-latency-us = <20>; exit-latency-us = <40>; min-residency-us = <90>; }; CLUSTER_RETENTION_1: cluster-retention-1 { compatible = "arm,idle-state"; local-timer-stop; arm,psci-suspend-param = <0x1010000>; entry-latency-us = <50>; exit-latency-us = <100>; min-residency-us = <270>; wakeup-latency-us = <100>; }; CPU_SLEEP_1_0: cpu-sleep-1-0 { compatible = "arm,idle-state"; local-timer-stop; arm,psci-suspend-param = <0x0010000>; entry-latency-us = <70>; exit-latency-us = <100>; min-residency-us = <300>; wakeup-latency-us = <150>; }; CLUSTER_SLEEP_1: cluster-sleep-1 { compatible = "arm,idle-state"; local-timer-stop; arm,psci-suspend-param = <0x1010000>; entry-latency-us = <500>; exit-latency-us = <1200>; min-residency-us = <3500>; wakeup-latency-us = <1300>; }; }; }; - | // Example 2 (ARM 32-bit, 8-cpu system, two clusters): cpus { #size-cells = <0>; #address-cells = <1>; cpu@0 { device_type = "cpu"; compatible = "arm,cortex-a15"; reg = <0x0>; cpu-idle-states = <&cpu_sleep_0_0>, <&cluster_sleep_0>; }; cpu@1 { device_type = "cpu"; compatible = "arm,cortex-a15"; reg = <0x1>; cpu-idle-states = <&cpu_sleep_0_0>, <&cluster_sleep_0>; }; cpu@2 { device_type = "cpu"; compatible = "arm,cortex-a15"; reg = <0x2>; cpu-idle-states = <&cpu_sleep_0_0>, <&cluster_sleep_0>; }; cpu@3 { device_type = "cpu"; compatible = "arm,cortex-a15"; reg = <0x3>; cpu-idle-states = <&cpu_sleep_0_0>, <&cluster_sleep_0>; }; cpu@100 { device_type = "cpu"; compatible = "arm,cortex-a7"; reg = <0x100>; cpu-idle-states = <&cpu_sleep_1_0>, <&cluster_sleep_1>; }; cpu@101 { device_type = "cpu"; compatible = "arm,cortex-a7"; reg = <0x101>; cpu-idle-states = <&cpu_sleep_1_0>, <&cluster_sleep_1>; }; cpu@102 { device_type = "cpu"; compatible = "arm,cortex-a7"; reg = <0x102>; cpu-idle-states = <&cpu_sleep_1_0>, <&cluster_sleep_1>; }; cpu@103 { device_type = "cpu"; compatible = "arm,cortex-a7"; reg = <0x103>; cpu-idle-states = <&cpu_sleep_1_0>, <&cluster_sleep_1>; }; idle-states { cpu_sleep_0_0: cpu-sleep-0-0 { compatible = "arm,idle-state"; local-timer-stop; entry-latency-us = <200>; exit-latency-us = <100>; min-residency-us = <400>; wakeup-latency-us = <250>; }; cluster_sleep_0: cluster-sleep-0 { compatible = "arm,idle-state"; local-timer-stop; entry-latency-us = <500>; exit-latency-us = <1500>; min-residency-us = <2500>; wakeup-latency-us = <1700>; }; cpu_sleep_1_0: cpu-sleep-1-0 { compatible = "arm,idle-state"; local-timer-stop; entry-latency-us = <300>; exit-latency-us = <500>; min-residency-us = <900>; wakeup-latency-us = <600>; }; cluster_sleep_1: cluster-sleep-1 { compatible = "arm,idle-state"; local-timer-stop; entry-latency-us = <800>; exit-latency-us = <2000>; min-residency-us = <6500>; wakeup-latency-us = <2300>; }; }; }; - | // Example 3 (RISC-V 64-bit, 4-cpu systems, two clusters): cpus { #size-cells = <0>; #address-cells = <1>; cpu@0 { device_type = "cpu"; compatible = "riscv"; reg = <0x0>; riscv,isa = "rv64imafdc"; mmu-type = "riscv,sv48"; cpu-idle-states = <&CPU_RET_0_0>, <&CPU_NONRET_0_0>, <&CLUSTER_RET_0>, <&CLUSTER_NONRET_0>; cpu_intc0: interrupt-controller { #interrupt-cells = <1>; compatible = "riscv,cpu-intc"; interrupt-controller; }; }; cpu@1 { device_type = "cpu"; compatible = "riscv"; reg = <0x1>; riscv,isa = "rv64imafdc"; mmu-type = "riscv,sv48"; cpu-idle-states = <&CPU_RET_0_0>, <&CPU_NONRET_0_0>, <&CLUSTER_RET_0>, <&CLUSTER_NONRET_0>; cpu_intc1: interrupt-controller { #interrupt-cells = <1>; compatible = "riscv,cpu-intc"; interrupt-controller; }; }; cpu@10 { device_type = "cpu"; compatible = "riscv"; reg = <0x10>; riscv,isa = "rv64imafdc"; mmu-type = "riscv,sv48"; cpu-idle-states = <&CPU_RET_1_0>, <&CPU_NONRET_1_0>, <&CLUSTER_RET_1>, <&CLUSTER_NONRET_1>; cpu_intc10: interrupt-controller { #interrupt-cells = <1>; compatible = "riscv,cpu-intc"; interrupt-controller; }; }; cpu@11 { device_type = "cpu"; compatible = "riscv"; reg = <0x11>; riscv,isa = "rv64imafdc"; mmu-type = "riscv,sv48"; cpu-idle-states = <&CPU_RET_1_0>, <&CPU_NONRET_1_0>, <&CLUSTER_RET_1>, <&CLUSTER_NONRET_1>; cpu_intc11: interrupt-controller { #interrupt-cells = <1>; compatible = "riscv,cpu-intc"; interrupt-controller; }; }; idle-states { CPU_RET_0_0: cpu-retentive-0-0 { compatible = "riscv,idle-state"; riscv,sbi-suspend-param = <0x10000000>; entry-latency-us = <20>; exit-latency-us = <40>; min-residency-us = <80>; }; CPU_NONRET_0_0: cpu-nonretentive-0-0 { compatible = "riscv,idle-state"; riscv,sbi-suspend-param = <0x90000000>; entry-latency-us = <250>; exit-latency-us = <500>; min-residency-us = <950>; }; CLUSTER_RET_0: cluster-retentive-0 { compatible = "riscv,idle-state"; riscv,sbi-suspend-param = <0x11000000>; local-timer-stop; entry-latency-us = <50>; exit-latency-us = <100>; min-residency-us = <250>; wakeup-latency-us = <130>; }; CLUSTER_NONRET_0: cluster-nonretentive-0 { compatible = "riscv,idle-state"; riscv,sbi-suspend-param = <0x91000000>; local-timer-stop; entry-latency-us = <600>; exit-latency-us = <1100>; min-residency-us = <2700>; wakeup-latency-us = <1500>; }; CPU_RET_1_0: cpu-retentive-1-0 { compatible = "riscv,idle-state"; riscv,sbi-suspend-param = <0x10000010>; entry-latency-us = <20>; exit-latency-us = <40>; min-residency-us = <80>; }; CPU_NONRET_1_0: cpu-nonretentive-1-0 { compatible = "riscv,idle-state"; riscv,sbi-suspend-param = <0x90000010>; entry-latency-us = <250>; exit-latency-us = <500>; min-residency-us = <950>; }; CLUSTER_RET_1: cluster-retentive-1 { compatible = "riscv,idle-state"; riscv,sbi-suspend-param = <0x11000010>; local-timer-stop; entry-latency-us = <50>; exit-latency-us = <100>; min-residency-us = <250>; wakeup-latency-us = <130>; }; CLUSTER_NONRET_1: cluster-nonretentive-1 { compatible = "riscv,idle-state"; riscv,sbi-suspend-param = <0x91000010>; local-timer-stop; entry-latency-us = <600>; exit-latency-us = <1100>; min-residency-us = <2700>; wakeup-latency-us = <1500>; }; }; }; // Example 4 - Qualcomm SPC idle-states { cpu_spc: cpu-spc { compatible = "qcom,idle-state-spc", "arm,idle-state"; entry-latency-us = <150>; exit-latency-us = <200>; min-residency-us = <2000>; }; }; ...