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authorLinus Torvalds2022-03-29 11:06:55 -0700
committerLinus Torvalds2022-03-29 11:06:55 -0700
commit1d59c3b669faddb91737f4e59c09305878a971d8 (patch)
treedc00847bb3bd096d95349729d2175a5e8770da68 /Documentation
parent5efabdadcf4a5b9a37847ecc85ba71cf2eff0fcf (diff)
parent3b65dd5be3c72b9d2013bfe6e9261e2b06222fa9 (diff)
Merge tag 'pm-5.18-rc1-2' of git://git.kernel.org/pub/scm/linux/kernel/git/rafael/linux-pm
Pull more power management updates from Rafael Wysocki: "These update ARM cpufreq drivers, the OPP (Operating Performance Points) library and the power management documentation. Specifics: - Add per core DVFS support for QCom SoC (Bjorn Andersson), convert to yaml binding (Manivannan Sadhasivam) and various other fixes to the QCom drivers (Luca Weiss). - Add OPP table for imx7s SoC (Denys Drozdov) and minor fixes (Stefan Agner). - Fix CPPC driver's freq/performance conversions (Pierre Gondois). - Minor generic cleanups (Yury Norov). - Introduce opp-microwatt property to the OPP core, bindings, etc (Lukasz Luba). - Convert DT bindings to schema format and various related fixes (Yassine Oudjana). - Expose OPP's OF node in debugfs (Viresh Kumar). - Add Intel uncore frequency scaling documentation file to its MAINTAINERS entry (Srinivas Pandruvada). - Clean up the AMD P-state driver documentation (Jan Engelhardt)" * tag 'pm-5.18-rc1-2' of git://git.kernel.org/pub/scm/linux/kernel/git/rafael/linux-pm: (24 commits) Documentation: amd-pstate: grammar and sentence structure updates dt-bindings: cpufreq: cpufreq-qcom-hw: Convert to YAML bindings dt-bindings: dvfs: Use MediaTek CPUFREQ HW as an example Documentation: EM: Describe new registration method using DT OPP: Add support of "opp-microwatt" for EM registration PM: EM: add macro to set .active_power() callback conditionally OPP: Add "opp-microwatt" supporting code dt-bindings: opp: Add "opp-microwatt" entry in the OPP MAINTAINERS: Add additional file to uncore frequency control cpufreq: blocklist Qualcomm sc8280xp and sa8540p in cpufreq-dt-platdev cpufreq: qcom-hw: Add support for per-core-dcvs dt-bindings: power: avs: qcom,cpr: Convert to DT schema arm64: dts: qcom: qcs404: Rename CPU and CPR OPP tables arm64: dts: qcom: msm8996: Rename cluster OPP tables dt-bindings: opp: Convert qcom-nvmem-cpufreq to DT schema dt-bindings: opp: qcom-opp: Convert to DT schema arm64: dts: qcom: msm8996-mtp: Add msm8996 compatible dt-bindings: arm: qcom: Add msm8996 and apq8096 compatibles opp: Expose of-node's name in debugfs cpufreq: CPPC: Fix performance/frequency conversion ...
Diffstat (limited to 'Documentation')
-rw-r--r--Documentation/admin-guide/pm/amd-pstate.rst135
-rw-r--r--Documentation/devicetree/bindings/cpufreq/cpufreq-qcom-hw.txt172
-rw-r--r--Documentation/devicetree/bindings/cpufreq/cpufreq-qcom-hw.yaml201
-rw-r--r--Documentation/devicetree/bindings/cpufreq/qcom-cpufreq-nvmem.yaml166
-rw-r--r--Documentation/devicetree/bindings/dvfs/performance-domain.yaml14
-rw-r--r--Documentation/devicetree/bindings/opp/opp-v2-base.yaml23
-rw-r--r--Documentation/devicetree/bindings/opp/opp-v2-kryo-cpu.yaml257
-rw-r--r--Documentation/devicetree/bindings/opp/opp-v2-qcom-level.yaml60
-rw-r--r--Documentation/devicetree/bindings/opp/qcom-nvmem-cpufreq.txt796
-rw-r--r--Documentation/devicetree/bindings/opp/qcom-opp.txt19
-rw-r--r--Documentation/devicetree/bindings/power/avs/qcom,cpr.txt130
-rw-r--r--Documentation/devicetree/bindings/power/avs/qcom,cpr.yaml160
-rw-r--r--Documentation/power/energy-model.rst10
13 files changed, 954 insertions, 1189 deletions
diff --git a/Documentation/admin-guide/pm/amd-pstate.rst b/Documentation/admin-guide/pm/amd-pstate.rst
index 1923cb25073b..83b58eb4ab4d 100644
--- a/Documentation/admin-guide/pm/amd-pstate.rst
+++ b/Documentation/admin-guide/pm/amd-pstate.rst
@@ -19,7 +19,7 @@ Linux kernel. The new mechanism is based on Collaborative Processor
Performance Control (CPPC) which provides finer grain frequency management
than legacy ACPI hardware P-States. Current AMD CPU/APU platforms are using
the ACPI P-states driver to manage CPU frequency and clocks with switching
-only in 3 P-states. CPPC replaces the ACPI P-states controls, allows a
+only in 3 P-states. CPPC replaces the ACPI P-states controls and allows a
flexible, low-latency interface for the Linux kernel to directly
communicate the performance hints to hardware.
@@ -27,7 +27,7 @@ communicate the performance hints to hardware.
``ondemand``, etc. to manage the performance hints which are provided by
CPPC hardware functionality that internally follows the hardware
specification (for details refer to AMD64 Architecture Programmer's Manual
-Volume 2: System Programming [1]_). Currently ``amd-pstate`` supports basic
+Volume 2: System Programming [1]_). Currently, ``amd-pstate`` supports basic
frequency control function according to kernel governors on some of the
Zen2 and Zen3 processors, and we will implement more AMD specific functions
in future after we verify them on the hardware and SBIOS.
@@ -41,9 +41,9 @@ continuous, abstract, and unit-less performance value in a scale that is
not tied to a specific performance state / frequency. This is an ACPI
standard [2]_ which software can specify application performance goals and
hints as a relative target to the infrastructure limits. AMD processors
-provides the low latency register model (MSR) instead of AML code
+provide the low latency register model (MSR) instead of an AML code
interpreter for performance adjustments. ``amd-pstate`` will initialize a
-``struct cpufreq_driver`` instance ``amd_pstate_driver`` with the callbacks
+``struct cpufreq_driver`` instance, ``amd_pstate_driver``, with the callbacks
to manage each performance update behavior. ::
Highest Perf ------>+-----------------------+ +-----------------------+
@@ -91,26 +91,26 @@ AMD CPPC Performance Capability
Highest Performance (RO)
.........................
-It is the absolute maximum performance an individual processor may reach,
+This is the absolute maximum performance an individual processor may reach,
assuming ideal conditions. This performance level may not be sustainable
for long durations and may only be achievable if other platform components
-are in a specific state; for example, it may require other processors be in
+are in a specific state; for example, it may require other processors to be in
an idle state. This would be equivalent to the highest frequencies
supported by the processor.
Nominal (Guaranteed) Performance (RO)
......................................
-It is the maximum sustained performance level of the processor, assuming
-ideal operating conditions. In absence of an external constraint (power,
-thermal, etc.) this is the performance level the processor is expected to
+This is the maximum sustained performance level of the processor, assuming
+ideal operating conditions. In the absence of an external constraint (power,
+thermal, etc.), this is the performance level the processor is expected to
be able to maintain continuously. All cores/processors are expected to be
able to sustain their nominal performance state simultaneously.
Lowest non-linear Performance (RO)
...................................
-It is the lowest performance level at which nonlinear power savings are
+This is the lowest performance level at which nonlinear power savings are
achieved, for example, due to the combined effects of voltage and frequency
scaling. Above this threshold, lower performance levels should be generally
more energy efficient than higher performance levels. This register
@@ -119,7 +119,7 @@ effectively conveys the most efficient performance level to ``amd-pstate``.
Lowest Performance (RO)
........................
-It is the absolute lowest performance level of the processor. Selecting a
+This is the absolute lowest performance level of the processor. Selecting a
performance level lower than the lowest nonlinear performance level may
cause an efficiency penalty but should reduce the instantaneous power
consumption of the processor.
@@ -149,14 +149,14 @@ a relative number. This can be expressed as percentage of nominal
performance (infrastructure max). Below the nominal sustained performance
level, desired performance expresses the average performance level of the
processor subject to hardware. Above the nominal performance level,
-processor must provide at least nominal performance requested and go higher
+the processor must provide at least nominal performance requested and go higher
if current operating conditions allow.
Energy Performance Preference (EPP) (RW)
.........................................
-Provides a hint to the hardware if software wants to bias toward performance
-(0x0) or energy efficiency (0xff).
+This attribute provides a hint to the hardware if software wants to bias
+toward performance (0x0) or energy efficiency (0xff).
Key Governors Support
@@ -173,35 +173,34 @@ operating frequencies supported by the hardware. Users can check the
``amd-pstate`` mainly supports ``schedutil`` and ``ondemand`` for dynamic
frequency control. It is to fine tune the processor configuration on
``amd-pstate`` to the ``schedutil`` with CPU CFS scheduler. ``amd-pstate``
-registers adjust_perf callback to implement the CPPC similar performance
-update behavior. It is initialized by ``sugov_start`` and then populate the
-CPU's update_util_data pointer to assign ``sugov_update_single_perf`` as
-the utilization update callback function in CPU scheduler. CPU scheduler
-will call ``cpufreq_update_util`` and assign the target performance
-according to the ``struct sugov_cpu`` that utilization update belongs to.
-Then ``amd-pstate`` updates the desired performance according to the CPU
+registers the adjust_perf callback to implement performance update behavior
+similar to CPPC. It is initialized by ``sugov_start`` and then populates the
+CPU's update_util_data pointer to assign ``sugov_update_single_perf`` as the
+utilization update callback function in the CPU scheduler. The CPU scheduler
+will call ``cpufreq_update_util`` and assigns the target performance according
+to the ``struct sugov_cpu`` that the utilization update belongs to.
+Then, ``amd-pstate`` updates the desired performance according to the CPU
scheduler assigned.
Processor Support
=======================
-The ``amd-pstate`` initialization will fail if the _CPC in ACPI SBIOS is
-not existed at the detected processor, and it uses ``acpi_cpc_valid`` to
-check the _CPC existence. All Zen based processors support legacy ACPI
-hardware P-States function, so while the ``amd-pstate`` fails to be
-initialized, the kernel will fall back to initialize ``acpi-cpufreq``
-driver.
+The ``amd-pstate`` initialization will fail if the ``_CPC`` entry in the ACPI
+SBIOS does not exist in the detected processor. It uses ``acpi_cpc_valid``
+to check the existence of ``_CPC``. All Zen based processors support the legacy
+ACPI hardware P-States function, so when ``amd-pstate`` fails initialization,
+the kernel will fall back to initialize the ``acpi-cpufreq`` driver.
There are two types of hardware implementations for ``amd-pstate``: one is
`Full MSR Support <perf_cap_>`_ and another is `Shared Memory Support
-<perf_cap_>`_. It can use :c:macro:`X86_FEATURE_CPPC` feature flag (for
-details refer to Processor Programming Reference (PPR) for AMD Family
-19h Model 51h, Revision A1 Processors [3]_) to indicate the different
-types. ``amd-pstate`` is to register different ``static_call`` instances
-for different hardware implementations.
+<perf_cap_>`_. It can use the :c:macro:`X86_FEATURE_CPPC` feature flag to
+indicate the different types. (For details, refer to the Processor Programming
+Reference (PPR) for AMD Family 19h Model 51h, Revision A1 Processors [3]_.)
+``amd-pstate`` is to register different ``static_call`` instances for different
+hardware implementations.
-Currently, some of Zen2 and Zen3 processors support ``amd-pstate``. In the
+Currently, some of the Zen2 and Zen3 processors support ``amd-pstate``. In the
future, it will be supported on more and more AMD processors.
Full MSR Support
@@ -210,18 +209,18 @@ Full MSR Support
Some new Zen3 processors such as Cezanne provide the MSR registers directly
while the :c:macro:`X86_FEATURE_CPPC` CPU feature flag is set.
``amd-pstate`` can handle the MSR register to implement the fast switch
-function in ``CPUFreq`` that can shrink latency of frequency control on the
-interrupt context. The functions with ``pstate_xxx`` prefix represent the
-operations of MSR registers.
+function in ``CPUFreq`` that can reduce the latency of frequency control in
+interrupt context. The functions with a ``pstate_xxx`` prefix represent the
+operations on MSR registers.
Shared Memory Support
----------------------
-If :c:macro:`X86_FEATURE_CPPC` CPU feature flag is not set, that means the
-processor supports shared memory solution. In this case, ``amd-pstate``
+If the :c:macro:`X86_FEATURE_CPPC` CPU feature flag is not set, the
+processor supports the shared memory solution. In this case, ``amd-pstate``
uses the ``cppc_acpi`` helper methods to implement the callback functions
-that defined on ``static_call``. The functions with ``cppc_xxx`` prefix
-represent the operations of acpi cppc helpers for shared memory solution.
+that are defined on ``static_call``. The functions with the ``cppc_xxx`` prefix
+represent the operations of ACPI CPPC helpers for the shared memory solution.
AMD P-States and ACPI hardware P-States always can be supported in one
@@ -234,7 +233,7 @@ User Space Interface in ``sysfs``
==================================
``amd-pstate`` exposes several global attributes (files) in ``sysfs`` to
-control its functionality at the system level. They located in the
+control its functionality at the system level. They are located in the
``/sys/devices/system/cpu/cpufreq/policyX/`` directory and affect all CPUs. ::
root@hr-test1:/home/ray# ls /sys/devices/system/cpu/cpufreq/policy0/*amd*
@@ -246,38 +245,38 @@ control its functionality at the system level. They located in the
``amd_pstate_highest_perf / amd_pstate_max_freq``
Maximum CPPC performance and CPU frequency that the driver is allowed to
-set in percent of the maximum supported CPPC performance level (the highest
+set, in percent of the maximum supported CPPC performance level (the highest
performance supported in `AMD CPPC Performance Capability <perf_cap_>`_).
-In some of ASICs, the highest CPPC performance is not the one in the _CPC
-table, so we need to expose it to sysfs. If boost is not active but
-supported, this maximum frequency will be larger than the one in
+In some ASICs, the highest CPPC performance is not the one in the ``_CPC``
+table, so we need to expose it to sysfs. If boost is not active, but
+still supported, this maximum frequency will be larger than the one in
``cpuinfo``.
This attribute is read-only.
``amd_pstate_lowest_nonlinear_freq``
-The lowest non-linear CPPC CPU frequency that the driver is allowed to set
-in percent of the maximum supported CPPC performance level (Please see the
+The lowest non-linear CPPC CPU frequency that the driver is allowed to set,
+in percent of the maximum supported CPPC performance level. (Please see the
lowest non-linear performance in `AMD CPPC Performance Capability
-<perf_cap_>`_).
+<perf_cap_>`_.)
This attribute is read-only.
-For other performance and frequency values, we can read them back from
+Other performance and frequency values can be read back from
``/sys/devices/system/cpu/cpuX/acpi_cppc/``, see :ref:`cppc_sysfs`.
``amd-pstate`` vs ``acpi-cpufreq``
======================================
-On majority of AMD platforms supported by ``acpi-cpufreq``, the ACPI tables
-provided by the platform firmware used for CPU performance scaling, but
-only provides 3 P-states on AMD processors.
-However, on modern AMD APU and CPU series, it provides the collaborative
-processor performance control according to ACPI protocol and customize this
-for AMD platforms. That is fine-grain and continuous frequency range
+On the majority of AMD platforms supported by ``acpi-cpufreq``, the ACPI tables
+provided by the platform firmware are used for CPU performance scaling, but
+only provide 3 P-states on AMD processors.
+However, on modern AMD APU and CPU series, hardware provides the Collaborative
+Processor Performance Control according to the ACPI protocol and customizes this
+for AMD platforms. That is, fine-grained and continuous frequency ranges
instead of the legacy hardware P-states. ``amd-pstate`` is the kernel
-module which supports the new AMD P-States mechanism on most of future AMD
-platforms. The AMD P-States mechanism will be the more performance and energy
+module which supports the new AMD P-States mechanism on most of the future AMD
+platforms. The AMD P-States mechanism is the more performance and energy
efficiency frequency management method on AMD processors.
Kernel Module Options for ``amd-pstate``
@@ -287,25 +286,25 @@ Kernel Module Options for ``amd-pstate``
Use a module param (shared_mem) to enable related processors manually with
**amd_pstate.shared_mem=1**.
Due to the performance issue on the processors with `Shared Memory Support
-<perf_cap_>`_, so we disable it for the moment and will enable this by default
-once we address performance issue on this solution.
+<perf_cap_>`_, we disable it presently and will re-enable this by default
+once we address performance issue with this solution.
-The way to check whether current processor is `Full MSR Support <perf_cap_>`_
+To check whether the current processor is using `Full MSR Support <perf_cap_>`_
or `Shared Memory Support <perf_cap_>`_ : ::
ray@hr-test1:~$ lscpu | grep cppc
Flags: fpu vme de pse tsc msr pae mce cx8 apic sep mtrr pge mca cmov pat pse36 clflush mmx fxsr sse sse2 ht syscall nx mmxext fxsr_opt pdpe1gb rdtscp lm constant_tsc rep_good nopl nonstop_tsc cpuid extd_apicid aperfmperf rapl pni pclmulqdq monitor ssse3 fma cx16 sse4_1 sse4_2 x2apic movbe popcnt aes xsave avx f16c rdrand lahf_lm cmp_legacy svm extapic cr8_legacy abm sse4a misalignsse 3dnowprefetch osvw ibs skinit wdt tce topoext perfctr_core perfctr_nb bpext perfctr_llc mwaitx cpb cat_l3 cdp_l3 hw_pstate ssbd mba ibrs ibpb stibp vmmcall fsgsbase bmi1 avx2 smep bmi2 erms invpcid cqm rdt_a rdseed adx smap clflushopt clwb sha_ni xsaveopt xsavec xgetbv1 xsaves cqm_llc cqm_occup_llc cqm_mbm_total cqm_mbm_local clzero irperf xsaveerptr rdpru wbnoinvd cppc arat npt lbrv svm_lock nrip_save tsc_scale vmcb_clean flushbyasid decodeassists pausefilter pfthreshold avic v_vmsave_vmload vgif v_spec_ctrl umip pku ospke vaes vpclmulqdq rdpid overflow_recov succor smca fsrm
-If CPU Flags have cppc, then this processor supports `Full MSR Support
-<perf_cap_>`_. Otherwise it supports `Shared Memory Support <perf_cap_>`_.
+If the CPU flags have ``cppc``, then this processor supports `Full MSR Support
+<perf_cap_>`_. Otherwise, it supports `Shared Memory Support <perf_cap_>`_.
``cpupower`` tool support for ``amd-pstate``
===============================================
-``amd-pstate`` is supported on ``cpupower`` tool that can be used to dump the frequency
-information. And it is in progress to support more and more operations for new
-``amd-pstate`` module with this tool. ::
+``amd-pstate`` is supported by the ``cpupower`` tool, which can be used to dump
+frequency information. Development is in progress to support more and more
+operations for the new ``amd-pstate`` module with this tool. ::
root@hr-test1:/home/ray# cpupower frequency-info
analyzing CPU 0:
@@ -336,10 +335,10 @@ Trace Events
--------------
There are two static trace events that can be used for ``amd-pstate``
-diagnostics. One of them is the cpu_frequency trace event generally used
+diagnostics. One of them is the ``cpu_frequency`` trace event generally used
by ``CPUFreq``, and the other one is the ``amd_pstate_perf`` trace event
specific to ``amd-pstate``. The following sequence of shell commands can
-be used to enable them and see their output (if the kernel is generally
+be used to enable them and see their output (if the kernel is
configured to support event tracing). ::
root@hr-test1:/home/ray# cd /sys/kernel/tracing/
@@ -364,7 +363,7 @@ configured to support event tracing). ::
<idle>-0 [003] d.s.. 4995.980971: amd_pstate_perf: amd_min_perf=85 amd_des_perf=85 amd_max_perf=166 cpu_id=3 changed=false fast_switch=true
<idle>-0 [011] d.s.. 4995.980996: amd_pstate_perf: amd_min_perf=85 amd_des_perf=85 amd_max_perf=166 cpu_id=11 changed=false fast_switch=true
-The cpu_frequency trace event will be triggered either by the ``schedutil`` scaling
+The ``cpu_frequency`` trace event will be triggered either by the ``schedutil`` scaling
governor (for the policies it is attached to), or by the ``CPUFreq`` core (for the
policies with other scaling governors).
diff --git a/Documentation/devicetree/bindings/cpufreq/cpufreq-qcom-hw.txt b/Documentation/devicetree/bindings/cpufreq/cpufreq-qcom-hw.txt
deleted file mode 100644
index 9299028ee712..000000000000
--- a/Documentation/devicetree/bindings/cpufreq/cpufreq-qcom-hw.txt
+++ /dev/null
@@ -1,172 +0,0 @@
-Qualcomm Technologies, Inc. CPUFREQ Bindings
-
-CPUFREQ HW is a hardware engine used by some Qualcomm Technologies, Inc. (QTI)
-SoCs to manage frequency in hardware. It is capable of controlling frequency
-for multiple clusters.
-
-Properties:
-- compatible
- Usage: required
- Value type: <string>
- Definition: must be "qcom,cpufreq-hw" or "qcom,cpufreq-epss".
-
-- clocks
- Usage: required
- Value type: <phandle> From common clock binding.
- Definition: clock handle for XO clock and GPLL0 clock.
-
-- clock-names
- Usage: required
- Value type: <string> From common clock binding.
- Definition: must be "xo", "alternate".
-
-- reg
- Usage: required
- Value type: <prop-encoded-array>
- Definition: Addresses and sizes for the memory of the HW bases in
- each frequency domain.
-- reg-names
- Usage: Optional
- Value type: <string>
- Definition: Frequency domain name i.e.
- "freq-domain0", "freq-domain1".
-
-- #freq-domain-cells:
- Usage: required.
- Definition: Number of cells in a freqency domain specifier.
-
-* Property qcom,freq-domain
-Devices supporting freq-domain must set their "qcom,freq-domain" property with
-phandle to a cpufreq_hw followed by the Domain ID(0/1) in the CPU DT node.
-
-
-Example:
-
-Example 1: Dual-cluster, Quad-core per cluster. CPUs within a cluster switch
-DCVS state together.
-
-/ {
- cpus {
- #address-cells = <2>;
- #size-cells = <0>;
-
- CPU0: cpu@0 {
- device_type = "cpu";
- compatible = "qcom,kryo385";
- reg = <0x0 0x0>;
- enable-method = "psci";
- next-level-cache = <&L2_0>;
- qcom,freq-domain = <&cpufreq_hw 0>;
- L2_0: l2-cache {
- compatible = "cache";
- next-level-cache = <&L3_0>;
- L3_0: l3-cache {
- compatible = "cache";
- };
- };
- };
-
- CPU1: cpu@100 {
- device_type = "cpu";
- compatible = "qcom,kryo385";
- reg = <0x0 0x100>;
- enable-method = "psci";
- next-level-cache = <&L2_100>;
- qcom,freq-domain = <&cpufreq_hw 0>;
- L2_100: l2-cache {
- compatible = "cache";
- next-level-cache = <&L3_0>;
- };
- };
-
- CPU2: cpu@200 {
- device_type = "cpu";
- compatible = "qcom,kryo385";
- reg = <0x0 0x200>;
- enable-method = "psci";
- next-level-cache = <&L2_200>;
- qcom,freq-domain = <&cpufreq_hw 0>;
- L2_200: l2-cache {
- compatible = "cache";
- next-level-cache = <&L3_0>;
- };
- };
-
- CPU3: cpu@300 {
- device_type = "cpu";
- compatible = "qcom,kryo385";
- reg = <0x0 0x300>;
- enable-method = "psci";
- next-level-cache = <&L2_300>;
- qcom,freq-domain = <&cpufreq_hw 0>;
- L2_300: l2-cache {
- compatible = "cache";
- next-level-cache = <&L3_0>;
- };
- };
-
- CPU4: cpu@400 {
- device_type = "cpu";
- compatible = "qcom,kryo385";
- reg = <0x0 0x400>;
- enable-method = "psci";
- next-level-cache = <&L2_400>;
- qcom,freq-domain = <&cpufreq_hw 1>;
- L2_400: l2-cache {
- compatible = "cache";
- next-level-cache = <&L3_0>;
- };
- };
-
- CPU5: cpu@500 {
- device_type = "cpu";
- compatible = "qcom,kryo385";
- reg = <0x0 0x500>;
- enable-method = "psci";
- next-level-cache = <&L2_500>;
- qcom,freq-domain = <&cpufreq_hw 1>;
- L2_500: l2-cache {
- compatible = "cache";
- next-level-cache = <&L3_0>;
- };
- };
-
- CPU6: cpu@600 {
- device_type = "cpu";
- compatible = "qcom,kryo385";
- reg = <0x0 0x600>;
- enable-method = "psci";
- next-level-cache = <&L2_600>;
- qcom,freq-domain = <&cpufreq_hw 1>;
- L2_600: l2-cache {
- compatible = "cache";
- next-level-cache = <&L3_0>;
- };
- };
-
- CPU7: cpu@700 {
- device_type = "cpu";
- compatible = "qcom,kryo385";
- reg = <0x0 0x700>;
- enable-method = "psci";
- next-level-cache = <&L2_700>;
- qcom,freq-domain = <&cpufreq_hw 1>;
- L2_700: l2-cache {
- compatible = "cache";
- next-level-cache = <&L3_0>;
- };
- };
- };
-
- soc {
- cpufreq_hw: cpufreq@17d43000 {
- compatible = "qcom,cpufreq-hw";
- reg = <0x17d43000 0x1400>, <0x17d45800 0x1400>;
- reg-names = "freq-domain0", "freq-domain1";
-
- clocks = <&rpmhcc RPMH_CXO_CLK>, <&gcc GPLL0>;
- clock-names = "xo", "alternate";
-
- #freq-domain-cells = <1>;
- };
-}
diff --git a/Documentation/devicetree/bindings/cpufreq/cpufreq-qcom-hw.yaml b/Documentation/devicetree/bindings/cpufreq/cpufreq-qcom-hw.yaml
new file mode 100644
index 000000000000..2f1b8b6852a0
--- /dev/null
+++ b/Documentation/devicetree/bindings/cpufreq/cpufreq-qcom-hw.yaml
@@ -0,0 +1,201 @@
+# SPDX-License-Identifier: GPL-2.0-only OR BSD-2-Clause
+%YAML 1.2
+---
+$id: http://devicetree.org/schemas/cpufreq/cpufreq-qcom-hw.yaml#
+$schema: http://devicetree.org/meta-schemas/core.yaml#
+
+title: Qualcomm Technologies, Inc. CPUFREQ
+
+maintainers:
+ - Manivannan Sadhasivam <manivannan.sadhasivam@linaro.org>
+
+description: |
+
+ CPUFREQ HW is a hardware engine used by some Qualcomm Technologies, Inc. (QTI)
+ SoCs to manage frequency in hardware. It is capable of controlling frequency
+ for multiple clusters.
+
+properties:
+ compatible:
+ oneOf:
+ - description: v1 of CPUFREQ HW
+ items:
+ - const: qcom,cpufreq-hw
+
+ - description: v2 of CPUFREQ HW (EPSS)
+ items:
+ - enum:
+ - qcom,sm8250-cpufreq-epss
+ - const: qcom,cpufreq-epss
+
+ reg:
+ minItems: 2
+ items:
+ - description: Frequency domain 0 register region
+ - description: Frequency domain 1 register region
+ - description: Frequency domain 2 register region
+
+ reg-names:
+ minItems: 2
+ items:
+ - const: freq-domain0
+ - const: freq-domain1
+ - const: freq-domain2
+
+ clocks:
+ items:
+ - description: XO Clock
+ - description: GPLL0 Clock
+
+ clock-names:
+ items:
+ - const: xo
+ - const: alternate
+
+ '#freq-domain-cells':
+ const: 1
+
+required:
+ - compatible
+ - reg
+ - clocks
+ - clock-names
+ - '#freq-domain-cells'
+
+additionalProperties: false
+
+examples:
+ - |
+ #include <dt-bindings/clock/qcom,gcc-sdm845.h>
+ #include <dt-bindings/clock/qcom,rpmh.h>
+
+ // Example 1: Dual-cluster, Quad-core per cluster. CPUs within a cluster
+ // switch DCVS state together.
+ cpus {
+ #address-cells = <2>;
+ #size-cells = <0>;
+
+ CPU0: cpu@0 {
+ device_type = "cpu";
+ compatible = "qcom,kryo385";
+ reg = <0x0 0x0>;
+ enable-method = "psci";
+ next-level-cache = <&L2_0>;
+ qcom,freq-domain = <&cpufreq_hw 0>;
+ L2_0: l2-cache {
+ compatible = "cache";
+ next-level-cache = <&L3_0>;
+ L3_0: l3-cache {
+ compatible = "cache";
+ };
+ };
+ };
+
+ CPU1: cpu@100 {
+ device_type = "cpu";
+ compatible = "qcom,kryo385";
+ reg = <0x0 0x100>;
+ enable-method = "psci";
+ next-level-cache = <&L2_100>;
+ qcom,freq-domain = <&cpufreq_hw 0>;
+ L2_100: l2-cache {
+ compatible = "cache";
+ next-level-cache = <&L3_0>;
+ };
+ };
+
+ CPU2: cpu@200 {
+ device_type = "cpu";
+ compatible = "qcom,kryo385";
+ reg = <0x0 0x200>;
+ enable-method = "psci";
+ next-level-cache = <&L2_200>;
+ qcom,freq-domain = <&cpufreq_hw 0>;
+ L2_200: l2-cache {
+ compatible = "cache";
+ next-level-cache = <&L3_0>;
+ };
+ };
+
+ CPU3: cpu@300 {
+ device_type = "cpu";
+ compatible = "qcom,kryo385";
+ reg = <0x0 0x300>;
+ enable-method = "psci";
+ next-level-cache = <&L2_300>;
+ qcom,freq-domain = <&cpufreq_hw 0>;
+ L2_300: l2-cache {
+ compatible = "cache";
+ next-level-cache = <&L3_0>;
+ };
+ };
+
+ CPU4: cpu@400 {
+ device_type = "cpu";
+ compatible = "qcom,kryo385";
+ reg = <0x0 0x400>;
+ enable-method = "psci";
+ next-level-cache = <&L2_400>;
+ qcom,freq-domain = <&cpufreq_hw 1>;
+ L2_400: l2-cache {
+ compatible = "cache";
+ next-level-cache = <&L3_0>;
+ };
+ };
+
+ CPU5: cpu@500 {
+ device_type = "cpu";
+ compatible = "qcom,kryo385";
+ reg = <0x0 0x500>;
+ enable-method = "psci";
+ next-level-cache = <&L2_500>;
+ qcom,freq-domain = <&cpufreq_hw 1>;
+ L2_500: l2-cache {
+ compatible = "cache";
+ next-level-cache = <&L3_0>;
+ };
+ };
+
+ CPU6: cpu@600 {
+ device_type = "cpu";
+ compatible = "qcom,kryo385";
+ reg = <0x0 0x600>;
+ enable-method = "psci";
+ next-level-cache = <&L2_600>;
+ qcom,freq-domain = <&cpufreq_hw 1>;
+ L2_600: l2-cache {
+ compatible = "cache";
+ next-level-cache = <&L3_0>;
+ };
+ };
+
+ CPU7: cpu@700 {
+ device_type = "cpu";
+ compatible = "qcom,kryo385";
+ reg = <0x0 0x700>;
+ enable-method = "psci";
+ next-level-cache = <&L2_700>;
+ qcom,freq-domain = <&cpufreq_hw 1>;
+ L2_700: l2-cache {
+ compatible = "cache";
+ next-level-cache = <&L3_0>;
+ };
+ };
+ };
+
+ soc {
+ #address-cells = <1>;
+ #size-cells = <1>;
+
+ cpufreq@17d43000 {
+ compatible = "qcom,cpufreq-hw";
+ reg = <0x17d43000 0x1400>, <0x17d45800 0x1400>;
+ reg-names = "freq-domain0", "freq-domain1";
+
+ clocks = <&rpmhcc RPMH_CXO_CLK>, <&gcc GPLL0>;
+ clock-names = "xo", "alternate";
+
+ #freq-domain-cells = <1>;
+ };
+ };
+...
diff --git a/Documentation/devicetree/bindings/cpufreq/qcom-cpufreq-nvmem.yaml b/Documentation/devicetree/bindings/cpufreq/qcom-cpufreq-nvmem.yaml
new file mode 100644
index 000000000000..a9a776da5505
--- /dev/null
+++ b/Documentation/devicetree/bindings/cpufreq/qcom-cpufreq-nvmem.yaml
@@ -0,0 +1,166 @@
+# SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause)
+%YAML 1.2
+---
+$id: http://devicetree.org/schemas/cpufreq/qcom-cpufreq-nvmem.yaml#
+$schema: http://devicetree.org/meta-schemas/core.yaml#
+
+title: Qualcomm Technologies, Inc. NVMEM CPUFreq bindings
+
+maintainers:
+ - Ilia Lin <ilia.lin@kernel.org>
+
+description: |
+ In certain Qualcomm Technologies, Inc. SoCs such as QCS404, The CPU supply
+ voltage is dynamically configured by Core Power Reduction (CPR) depending on
+ current CPU frequency and efuse values.
+ CPR provides a power domain with multiple levels that are selected depending
+ on the CPU OPP in use. The CPUFreq driver sets the CPR power domain level
+ according to the required OPPs defined in the CPU OPP tables.
+
+select:
+ properties:
+ compatible:
+ contains:
+ enum:
+ - qcom,qcs404
+ required:
+ - compatible
+
+properties:
+ cpus:
+ type: object
+
+ patternProperties:
+ 'cpu@[0-9a-f]+':
+ type: object
+
+ properties:
+ power-domains:
+ maxItems: 1
+
+ power-domain-names:
+ items:
+ - const: cpr
+
+ required:
+ - power-domains
+ - power-domain-names
+
+patternProperties:
+ '^opp-table(-[a-z0-9]+)?$':
+ if:
+ properties:
+ compatible:
+ const: operating-points-v2-kryo-cpu
+ then:
+ patternProperties:
+ '^opp-?[0-9]+$':
+ required:
+ - required-opps
+
+additionalProperties: true
+
+examples:
+ - |
+ / {
+ model = "Qualcomm Technologies, Inc. QCS404";
+ compatible = "qcom,qcs404";
+ #address-cells = <2>;
+ #size-cells = <2>;
+
+ cpus {
+ #address-cells = <1>;
+ #size-cells = <0>;
+
+ CPU0: cpu@100 {
+ device_type = "cpu";
+ compatible = "arm,cortex-a53";
+ reg = <0x100>;
+ enable-method = "psci";
+ cpu-idle-states = <&CPU_SLEEP_0>;
+ next-level-cache = <&L2_0>;
+ #cooling-cells = <2>;
+ clocks = <&apcs_glb>;
+ operating-points-v2 = <&cpu_opp_table>;
+ power-domains = <&cpr>;
+ power-domain-names = "cpr";
+ };
+
+ CPU1: cpu@101 {
+ device_type = "cpu";
+ compatible = "arm,cortex-a53";
+ reg = <0x101>;
+ enable-method = "psci";
+ cpu-idle-states = <&CPU_SLEEP_0>;
+ next-level-cache = <&L2_0>;
+ #cooling-cells = <2>;
+ clocks = <&apcs_glb>;
+ operating-points-v2 = <&cpu_opp_table>;
+ power-domains = <&cpr>;
+ power-domain-names = "cpr";
+ };
+
+ CPU2: cpu@102 {
+ device_type = "cpu";
+ compatible = "arm,cortex-a53";
+ reg = <0x102>;
+ enable-method = "psci";
+ cpu-idle-states = <&CPU_SLEEP_0>;
+ next-level-cache = <&L2_0>;
+ #cooling-cells = <2>;
+ clocks = <&apcs_glb>;
+ operating-points-v2 = <&cpu_opp_table>;
+ power-domains = <&cpr>;
+ power-domain-names = "cpr";
+ };
+
+ CPU3: cpu@103 {
+ device_type = "cpu";
+ compatible = "arm,cortex-a53";
+ reg = <0x103>;
+ enable-method = "psci";
+ cpu-idle-states = <&CPU_SLEEP_0>;
+ next-level-cache = <&L2_0>;
+ #cooling-cells = <2>;
+ clocks = <&apcs_glb>;
+ operating-points-v2 = <&cpu_opp_table>;
+ power-domains = <&cpr>;
+ power-domain-names = "cpr";
+ };
+ };
+
+ cpu_opp_table: opp-table-cpu {
+ compatible = "operating-points-v2-kryo-cpu";
+ opp-shared;
+
+ opp-1094400000 {
+ opp-hz = /bits/ 64 <1094400000>;
+ required-opps = <&cpr_opp1>;
+ };
+ opp-1248000000 {
+ opp-hz = /bits/ 64 <1248000000>;
+ required-opps = <&cpr_opp2>;
+ };
+ opp-1401600000 {
+ opp-hz = /bits/ 64 <1401600000>;
+ required-opps = <&cpr_opp3>;
+ };
+ };
+
+ cpr_opp_table: opp-table-cpr {
+ compatible = "operating-points-v2-qcom-level";
+
+ cpr_opp1: opp1 {
+ opp-level = <1>;
+ qcom,opp-fuse-level = <1>;
+ };
+ cpr_opp2: opp2 {
+ opp-level = <2>;
+ qcom,opp-fuse-level = <2>;
+ };
+ cpr_opp3: opp3 {
+ opp-level = <3>;
+ qcom,opp-fuse-level = <3>;
+ };
+ };
+ };
diff --git a/Documentation/devicetree/bindings/dvfs/performance-domain.yaml b/Documentation/devicetree/bindings/dvfs/performance-domain.yaml
index 7959d40ded5a..1dcb85a02a76 100644
--- a/Documentation/devicetree/bindings/dvfs/performance-domain.yaml
+++ b/Documentation/devicetree/bindings/dvfs/performance-domain.yaml
@@ -51,10 +51,16 @@ additionalProperties: true
examples:
- |
- performance: performance-controller@12340000 {
- compatible = "qcom,cpufreq-hw";
- reg = <0x12340000 0x1000>;
- #performance-domain-cells = <1>;
+ soc {
+ #address-cells = <2>;
+ #size-cells = <2>;
+
+ performance: performance-controller@11bc00 {
+ compatible = "mediatek,cpufreq-hw";
+ reg = <0 0x0011bc10 0 0x120>, <0 0x0011bd30 0 0x120>;
+
+ #performance-domain-cells = <1>;
+ };
};
// The node above defines a performance controller that is a performance
diff --git a/Documentation/devicetree/bindings/opp/opp-v2-base.yaml b/Documentation/devicetree/bindings/opp/opp-v2-base.yaml
index da0f09eedc0c..76c8acd981b3 100644
--- a/Documentation/devicetree/bindings/opp/opp-v2-base.yaml
+++ b/Documentation/devicetree/bindings/opp/opp-v2-base.yaml
@@ -93,6 +93,21 @@ patternProperties:
minItems: 1
maxItems: 8 # Should be enough regulators
+ opp-microwatt:
+ description: |
+ The power for the OPP in micro-Watts.
+
+ Entries for multiple regulators shall be provided in the same field
+ separated by angular brackets <>. If current values aren't required
+ for a regulator, then it shall be filled with 0. If power values
+ aren't required for any of the regulators, then this field is not
+ required. The OPP binding doesn't provide any provisions to relate the
+ values to their power supplies or the order in which the supplies need
+ to be configured and that is left for the implementation specific
+ binding.
+ minItems: 1
+ maxItems: 8 # Should be enough regulators
+
opp-level:
description:
A value representing the performance level of the device.
@@ -205,6 +220,14 @@ patternProperties:
minItems: 1
maxItems: 8 # Should be enough regulators
+ '^opp-microwatt':
+ description:
+ Named opp-microwatt property. Similar to opp-microamp property,
+ but for microwatt instead.
+ $ref: /schemas/types.yaml#/definitions/uint32-array
+ minItems: 1
+ maxItems: 8 # Should be enough regulators
+
dependencies:
opp-avg-kBps: [ opp-peak-kBps ]
diff --git a/Documentation/devicetree/bindings/opp/opp-v2-kryo-cpu.yaml b/Documentation/devicetree/bindings/opp/opp-v2-kryo-cpu.yaml
new file mode 100644
index 000000000000..8c2e9ac5f68d
--- /dev/null
+++ b/Documentation/devicetree/bindings/opp/opp-v2-kryo-cpu.yaml
@@ -0,0 +1,257 @@
+# SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause)
+%YAML 1.2
+---
+$id: http://devicetree.org/schemas/opp/opp-v2-kryo-cpu.yaml#
+$schema: http://devicetree.org/meta-schemas/core.yaml#
+
+title: Qualcomm Technologies, Inc. NVMEM OPP bindings
+
+maintainers:
+ - Ilia Lin <ilia.lin@kernel.org>
+
+allOf:
+ - $ref: opp-v2-base.yaml#
+
+description: |
+ In certain Qualcomm Technologies, Inc. SoCs like APQ8096 and MSM8996,
+ the CPU frequencies subset and voltage value of each OPP varies based on
+ the silicon variant in use.
+ Qualcomm Technologies, Inc. Process Voltage Scaling Tables
+ defines the voltage and frequency value based on the msm-id in SMEM
+ and speedbin blown in the efuse combination.
+ The qcom-cpufreq-nvmem driver reads the msm-id and efuse value from the SoC
+ to provide the OPP framework with required information (existing HW bitmap).
+ This is used to determine the voltage and frequency value for each OPP of
+ operating-points-v2 table when it is parsed by the OPP framework.
+
+properties:
+ compatible:
+ const: operating-points-v2-kryo-cpu
+
+ nvmem-cells:
+ description: |
+ A phandle pointing to a nvmem-cells node representing the
+ efuse registers that has information about the
+ speedbin that is used to select the right frequency/voltage
+ value pair.
+
+ opp-shared: true
+
+patternProperties:
+ '^opp-?[0-9]+$':
+ type: object
+
+ properties:
+ opp-hz: true
+
+ opp-microvolt: true
+
+ opp-supported-hw:
+ description: |
+ A single 32 bit bitmap value, representing compatible HW.
+ Bitmap:
+ 0: MSM8996 V3, speedbin 0
+ 1: MSM8996 V3, speedbin 1
+ 2: MSM8996 V3, speedbin 2
+ 3: unused
+ 4: MSM8996 SG, speedbin 0
+ 5: MSM8996 SG, speedbin 1
+ 6: MSM8996 SG, speedbin 2
+ 7-31: unused
+ maximum: 0x77
+
+ clock-latency-ns: true
+
+ required-opps: true
+
+ required:
+ - opp-hz
+
+required:
+ - compatible
+
+if:
+ required:
+ - nvmem-cells
+then:
+ patternProperties:
+ '^opp-?[0-9]+$':
+ required:
+ - opp-supported-hw
+
+additionalProperties: false
+
+examples:
+ - |
+ / {
+ model = "Qualcomm Technologies, Inc. DB820c";
+ compatible = "arrow,apq8096-db820c", "qcom,apq8096-sbc", "qcom,apq8096";
+ #address-cells = <2>;
+ #size-cells = <2>;
+
+ cpus {
+ #address-cells = <2>;
+ #size-cells = <0>;
+
+ CPU0: cpu@0 {
+ device_type = "cpu";
+ compatible = "qcom,kryo";
+ reg = <0x0 0x0>;
+ enable-method = "psci";
+ cpu-idle-states = <&CPU_SLEEP_0>;
+ capacity-dmips-mhz = <1024>;
+ clocks = <&kryocc 0>;
+ operating-points-v2 = <&cluster0_opp>;
+ #cooling-cells = <2>;
+ next-level-cache = <&L2_0>;
+ L2_0: l2-cache {
+ compatible = "cache";
+ cache-level = <2>;
+ };
+ };
+
+ CPU1: cpu@1 {
+ device_type = "cpu";
+ compatible = "qcom,kryo";
+ reg = <0x0 0x1>;
+ enable-method = "psci";
+ cpu-idle-states = <&CPU_SLEEP_0>;
+ capacity-dmips-mhz = <1024>;
+ clocks = <&kryocc 0>;
+ operating-points-v2 = <&cluster0_opp>;
+ #cooling-cells = <2>;
+ next-level-cache = <&L2_0>;
+ };
+
+ CPU2: cpu@100 {
+ device_type = "cpu";
+ compatible = "qcom,kryo";
+ reg = <0x0 0x100>;
+ enable-method = "psci";
+ cpu-idle-states = <&CPU_SLEEP_0>;
+ capacity-dmips-mhz = <1024>;
+ clocks = <&kryocc 1>;
+ operating-points-v2 = <&cluster1_opp>;
+ #cooling-cells = <2>;
+ next-level-cache = <&L2_1>;
+ L2_1: l2-cache {
+ compatible = "cache";
+ cache-level = <2>;
+ };
+ };
+
+ CPU3: cpu@101 {
+ device_type = "cpu";
+ compatible = "qcom,kryo";
+ reg = <0x0 0x101>;
+ enable-method = "psci";
+ cpu-idle-states = <&CPU_SLEEP_0>;
+ capacity-dmips-mhz = <1024>;
+ clocks = <&kryocc 1>;
+ operating-points-v2 = <&cluster1_opp>;
+ #cooling-cells = <2>;
+ next-level-cache = <&L2_1>;
+ };
+
+ cpu-map {
+ cluster0 {
+ core0 {
+ cpu = <&CPU0>;
+ };
+
+ core1 {
+ cpu = <&CPU1>;
+ };
+ };
+
+ cluster1 {
+ core0 {
+ cpu = <&CPU2>;
+ };
+
+ core1 {
+ cpu = <&CPU3>;
+ };
+ };
+ };
+ };
+
+ cluster0_opp: opp-table-0 {
+ compatible = "operating-points-v2-kryo-cpu";
+ nvmem-cells = <&speedbin_efuse>;
+ opp-shared;
+
+ opp-307200000 {
+ opp-hz = /bits/ 64 <307200000>;
+ opp-microvolt = <905000 905000 1140000>;
+ opp-supported-hw = <0x77>;
+ clock-latency-ns = <200000>;
+ };
+ opp-1593600000 {
+ opp-hz = /bits/ 64 <1593600000>;
+ opp-microvolt = <1140000 905000 1140000>;
+ opp-supported-hw = <0x71>;
+ clock-latency-ns = <200000>;
+ };
+ opp-2188800000 {
+ opp-hz = /bits/ 64 <2188800000>;
+ opp-microvolt = <1140000 905000 1140000>;
+ opp-supported-hw = <0x10>;
+ clock-latency-ns = <200000>;
+ };
+ };
+
+ cluster1_opp: opp-table-1 {
+ compatible = "operating-points-v2-kryo-cpu";
+ nvmem-cells = <&speedbin_efuse>;
+ opp-shared;
+
+ opp-307200000 {
+ opp-hz = /bits/ 64 <307200000>;
+ opp-microvolt = <905000 905000 1140000>;
+ opp-supported-hw = <0x77>;
+ clock-latency-ns = <200000>;
+ };
+ opp-1593600000 {
+ opp-hz = /bits/ 64 <1593600000>;
+ opp-microvolt = <1140000 905000 1140000>;
+ opp-supported-hw = <0x70>;
+ clock-latency-ns = <200000>;
+ };
+ opp-2150400000 {
+ opp-hz = /bits/ 64 <2150400000>;
+ opp-microvolt = <1140000 905000 1140000>;
+ opp-supported-hw = <0x31>;
+ clock-latency-ns = <200000>;
+ };
+ opp-2342400000 {
+ opp-hz = /bits/ 64 <2342400000>;
+ opp-microvolt = <1140000 905000 1140000>;
+ opp-supported-hw = <0x10>;
+ clock-latency-ns = <200000>;
+ };
+ };
+
+ smem {
+ compatible = "qcom,smem";
+ memory-region = <&smem_mem>;
+ hwlocks = <&tcsr_mutex 3>;
+ };
+
+ soc {
+ #address-cells = <1>;
+ #size-cells = <1>;
+
+ qfprom: qfprom@74000 {
+ compatible = "qcom,msm8996-qfprom", "qcom,qfprom";
+ reg = <0x00074000 0x8ff>;
+ #address-cells = <1>;
+ #size-cells = <1>;
+
+ speedbin_efuse: speedbin@133 {
+ reg = <0x133 0x1>;
+ bits = <5 3>;
+ };
+ };
+ };
+ };
diff --git a/Documentation/devicetree/bindings/opp/opp-v2-qcom-level.yaml b/Documentation/devicetree/bindings/opp/opp-v2-qcom-level.yaml
new file mode 100644
index 000000000000..14a7a689ad6d
--- /dev/null
+++ b/Documentation/devicetree/bindings/opp/opp-v2-qcom-level.yaml
@@ -0,0 +1,60 @@
+# SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause)
+%YAML 1.2
+---
+$id: http://devicetree.org/schemas/opp/opp-v2-qcom-level.yaml#
+$schema: http://devicetree.org/meta-schemas/core.yaml#
+
+title: Qualcomm OPP bindings to describe OPP nodes.
+
+maintainers:
+ - Niklas Cassel <nks@flawful.org>
+
+allOf:
+ - $ref: opp-v2-base.yaml#
+
+properties:
+ compatible:
+ const: operating-points-v2-qcom-level
+
+patternProperties:
+ '^opp-?[0-9]+$':
+ type: object
+
+ properties:
+ opp-level: true
+
+ qcom,opp-fuse-level:
+ description: |
+ A positive value representing the fuse corner/level associated with
+ this OPP node. Sometimes several corners/levels shares a certain fuse
+ corner/level. A fuse corner/level contains e.g. ref uV, min uV,
+ and max uV.
+ $ref: /schemas/types.yaml#/definitions/uint32
+
+ required:
+ - opp-level
+ - qcom,opp-fuse-level
+
+required:
+ - compatible
+
+additionalProperties: false
+
+examples:
+ - |
+ cpr_opp_table: opp-table-cpr {
+ compatible = "operating-points-v2-qcom-level";
+
+ cpr_opp1: opp1 {
+ opp-level = <1>;
+ qcom,opp-fuse-level = <1>;
+ };
+ cpr_opp2: opp2 {
+ opp-level = <2>;
+ qcom,opp-fuse-level = <2>;
+ };
+ cpr_opp3: opp3 {
+ opp-level = <3>;
+ qcom,opp-fuse-level = <3>;
+ };
+ };
diff --git a/Documentation/devicetree/bindings/opp/qcom-nvmem-cpufreq.txt b/Documentation/devicetree/bindings/opp/qcom-nvmem-cpufreq.txt
deleted file mode 100644
index 64f07417ecfb..000000000000
--- a/Documentation/devicetree/bindings/opp/qcom-nvmem-cpufreq.txt
+++ /dev/null
@@ -1,796 +0,0 @@
-Qualcomm Technologies, Inc. NVMEM CPUFreq and OPP bindings
-===================================
-
-In Certain Qualcomm Technologies, Inc. SoCs like apq8096 and msm8996,
-the CPU frequencies subset and voltage value of each OPP varies based on
-the silicon variant in use.
-Qualcomm Technologies, Inc. Process Voltage Scaling Tables
-defines the voltage and frequency value based on the msm-id in SMEM
-and speedbin blown in the efuse combination.
-The qcom-cpufreq-nvmem driver reads the msm-id and efuse value from the SoC
-to provide the OPP framework with required information (existing HW bitmap).
-This is used to determine the voltage and frequency value for each OPP of
-operating-points-v2 table when it is parsed by the OPP framework.
-
-Required properties:
---------------------
-In 'cpu' nodes:
-- operating-points-v2: Phandle to the operating-points-v2 table to use.
-
-In 'operating-points-v2' table:
-- compatible: Should be
- - 'operating-points-v2-kryo-cpu' for apq8096, msm8996, msm8974,
- apq8064, ipq8064, msm8960 and ipq8074.
-
-Optional properties:
---------------------
-In 'cpu' nodes:
-- power-domains: A phandle pointing to the PM domain specifier which provides
- the performance states available for active state management.
- Please refer to the power-domains bindings
- Documentation/devicetree/bindings/power/power_domain.txt
- and also examples below.
-- power-domain-names: Should be
- - 'cpr' for qcs404.
-
-In 'operating-points-v2' table:
-- nvmem-cells: A phandle pointing to a nvmem-cells node representing the
- efuse registers that has information about the
- speedbin that is used to select the right frequency/voltage
- value pair.
- Please refer the for nvmem-cells
- bindings Documentation/devicetree/bindings/nvmem/nvmem.txt
- and also examples below.
-
-In every OPP node:
-- opp-supported-hw: A single 32 bit bitmap value, representing compatible HW.
- Bitmap:
- 0: MSM8996 V3, speedbin 0
- 1: MSM8996 V3, speedbin 1
- 2: MSM8996 V3, speedbin 2
- 3: unused
- 4: MSM8996 SG, speedbin 0
- 5: MSM8996 SG, speedbin 1
- 6: MSM8996 SG, speedbin 2
- 7-31: unused
-
-Example 1:
----------
-
- cpus {
- #address-cells = <2>;
- #size-cells = <0>;
-
- CPU0: cpu@0 {
- device_type = "cpu";
- compatible = "qcom,kryo";
- reg = <0x0 0x0>;
- enable-method = "psci";
- clocks = <&kryocc 0>;
- cpu-supply = <&pm8994_s11_saw>;
- operating-points-v2 = <&cluster0_opp>;
- #cooling-cells = <2>;
- next-level-cache = <&L2_0>;
- L2_0: l2-cache {
- compatible = "cache";
- cache-level = <2>;
- };
- };
-
- CPU1: cpu@1 {
- device_type = "cpu";
- compatible = "qcom,kryo";
- reg = <0x0 0x1>;
- enable-method = "psci";
- clocks = <&kryocc 0>;
- cpu-supply = <&pm8994_s11_saw>;
- operating-points-v2 = <&cluster0_opp>;
- #cooling-cells = <2>;
- next-level-cache = <&L2_0>;
- };
-
- CPU2: cpu@100 {
- device_type = "cpu";
- compatible = "qcom,kryo";
- reg = <0x0 0x100>;
- enable-method = "psci";
- clocks = <&kryocc 1>;
- cpu-supply = <&pm8994_s11_saw>;
- operating-points-v2 = <&cluster1_opp>;
- #cooling-cells = <2>;
- next-level-cache = <&L2_1>;
- L2_1: l2-cache {
- compatible = "cache";
- cache-level = <2>;
- };
- };
-
- CPU3: cpu@101 {
- device_type = "cpu";
- compatible = "qcom,kryo";
- reg = <0x0 0x101>;
- enable-method = "psci";
- clocks = <&kryocc 1>;
- cpu-supply = <&pm8994_s11_saw>;
- operating-points-v2 = <&cluster1_opp>;
- #cooling-cells = <2>;
- next-level-cache = <&L2_1>;
- };
-
- cpu-map {
- cluster0 {
- core0 {
- cpu = <&CPU0>;
- };
-
- core1 {
- cpu = <&CPU1>;
- };
- };
-
- cluster1 {
- core0 {
- cpu = <&CPU2>;
- };
-
- core1 {
- cpu = <&CPU3>;
- };
- };
- };
- };
-
- cluster0_opp: opp_table0 {
- compatible = "operating-points-v2-kryo-cpu";
- nvmem-cells = <&speedbin_efuse>;
- opp-shared;
-
- opp-307200000 {
- opp-hz = /bits/ 64 <307200000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x77>;
- clock-latency-ns = <200000>;
- };
- opp-384000000 {
- opp-hz = /bits/ 64 <384000000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-422400000 {
- opp-hz = /bits/ 64 <422400000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-460800000 {
- opp-hz = /bits/ 64 <460800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-480000000 {
- opp-hz = /bits/ 64 <480000000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-537600000 {
- opp-hz = /bits/ 64 <537600000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-556800000 {
- opp-hz = /bits/ 64 <556800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-614400000 {
- opp-hz = /bits/ 64 <614400000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-652800000 {
- opp-hz = /bits/ 64 <652800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-691200000 {
- opp-hz = /bits/ 64 <691200000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-729600000 {
- opp-hz = /bits/ 64 <729600000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-768000000 {
- opp-hz = /bits/ 64 <768000000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-844800000 {
- opp-hz = /bits/ 64 <844800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x77>;
- clock-latency-ns = <200000>;
- };
- opp-902400000 {
- opp-hz = /bits/ 64 <902400000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-960000000 {
- opp-hz = /bits/ 64 <960000000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-979200000 {
- opp-hz = /bits/ 64 <979200000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1036800000 {
- opp-hz = /bits/ 64 <1036800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1056000000 {
- opp-hz = /bits/ 64 <1056000000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1113600000 {
- opp-hz = /bits/ 64 <1113600000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1132800000 {
- opp-hz = /bits/ 64 <1132800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1190400000 {
- opp-hz = /bits/ 64 <1190400000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1209600000 {
- opp-hz = /bits/ 64 <1209600000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1228800000 {
- opp-hz = /bits/ 64 <1228800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1286400000 {
- opp-hz = /bits/ 64 <1286400000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1324800000 {
- opp-hz = /bits/ 64 <1324800000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x5>;
- clock-latency-ns = <200000>;
- };
- opp-1363200000 {
- opp-hz = /bits/ 64 <1363200000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x72>;
- clock-latency-ns = <200000>;
- };
- opp-1401600000 {
- opp-hz = /bits/ 64 <1401600000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x5>;
- clock-latency-ns = <200000>;
- };
- opp-1440000000 {
- opp-hz = /bits/ 64 <1440000000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1478400000 {
- opp-hz = /bits/ 64 <1478400000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x1>;
- clock-latency-ns = <200000>;
- };
- opp-1497600000 {
- opp-hz = /bits/ 64 <1497600000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x4>;
- clock-latency-ns = <200000>;
- };
- opp-1516800000 {
- opp-hz = /bits/ 64 <1516800000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1593600000 {
- opp-hz = /bits/ 64 <1593600000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x71>;
- clock-latency-ns = <200000>;
- };
- opp-1996800000 {
- opp-hz = /bits/ 64 <1996800000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x20>;
- clock-latency-ns = <200000>;
- };
- opp-2188800000 {
- opp-hz = /bits/ 64 <2188800000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x10>;
- clock-latency-ns = <200000>;
- };
- };
-
- cluster1_opp: opp_table1 {
- compatible = "operating-points-v2-kryo-cpu";
- nvmem-cells = <&speedbin_efuse>;
- opp-shared;
-
- opp-307200000 {
- opp-hz = /bits/ 64 <307200000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x77>;
- clock-latency-ns = <200000>;
- };
- opp-384000000 {
- opp-hz = /bits/ 64 <384000000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-403200000 {
- opp-hz = /bits/ 64 <403200000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-460800000 {
- opp-hz = /bits/ 64 <460800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-480000000 {
- opp-hz = /bits/ 64 <480000000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-537600000 {
- opp-hz = /bits/ 64 <537600000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-556800000 {
- opp-hz = /bits/ 64 <556800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-614400000 {
- opp-hz = /bits/ 64 <614400000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-652800000 {
- opp-hz = /bits/ 64 <652800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-691200000 {
- opp-hz = /bits/ 64 <691200000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-729600000 {
- opp-hz = /bits/ 64 <729600000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-748800000 {
- opp-hz = /bits/ 64 <748800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-806400000 {
- opp-hz = /bits/ 64 <806400000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-825600000 {
- opp-hz = /bits/ 64 <825600000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-883200000 {
- opp-hz = /bits/ 64 <883200000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-902400000 {
- opp-hz = /bits/ 64 <902400000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-940800000 {
- opp-hz = /bits/ 64 <940800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-979200000 {
- opp-hz = /bits/ 64 <979200000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1036800000 {
- opp-hz = /bits/ 64 <1036800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1056000000 {
- opp-hz = /bits/ 64 <1056000000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1113600000 {
- opp-hz = /bits/ 64 <1113600000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1132800000 {
- opp-hz = /bits/ 64 <1132800000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1190400000 {
- opp-hz = /bits/ 64 <1190400000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1209600000 {
- opp-hz = /bits/ 64 <1209600000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1248000000 {
- opp-hz = /bits/ 64 <1248000000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1286400000 {
- opp-hz = /bits/ 64 <1286400000>;
- opp-microvolt = <905000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1324800000 {
- opp-hz = /bits/ 64 <1324800000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1363200000 {
- opp-hz = /bits/ 64 <1363200000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1401600000 {
- opp-hz = /bits/ 64 <1401600000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1440000000 {
- opp-hz = /bits/ 64 <1440000000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1478400000 {
- opp-hz = /bits/ 64 <1478400000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1516800000 {
- opp-hz = /bits/ 64 <1516800000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1555200000 {
- opp-hz = /bits/ 64 <1555200000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1593600000 {
- opp-hz = /bits/ 64 <1593600000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1632000000 {
- opp-hz = /bits/ 64 <1632000000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1670400000 {
- opp-hz = /bits/ 64 <1670400000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1708800000 {
- opp-hz = /bits/ 64 <1708800000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1747200000 {
- opp-hz = /bits/ 64 <1747200000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x70>;
- clock-latency-ns = <200000>;
- };
- opp-1785600000 {
- opp-hz = /bits/ 64 <1785600000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x7>;
- clock-latency-ns = <200000>;
- };
- opp-1804800000 {
- opp-hz = /bits/ 64 <1804800000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x6>;
- clock-latency-ns = <200000>;
- };
- opp-1824000000 {
- opp-hz = /bits/ 64 <1824000000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x71>;
- clock-latency-ns = <200000>;
- };
- opp-1900800000 {
- opp-hz = /bits/ 64 <1900800000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x74>;
- clock-latency-ns = <200000>;
- };
- opp-1920000000 {
- opp-hz = /bits/ 64 <1920000000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x1>;
- clock-latency-ns = <200000>;
- };
- opp-1977600000 {
- opp-hz = /bits/ 64 <1977600000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x30>;
- clock-latency-ns = <200000>;
- };
- opp-1996800000 {
- opp-hz = /bits/ 64 <1996800000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x1>;
- clock-latency-ns = <200000>;
- };
- opp-2054400000 {
- opp-hz = /bits/ 64 <2054400000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x30>;
- clock-latency-ns = <200000>;
- };
- opp-2073600000 {
- opp-hz = /bits/ 64 <2073600000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x1>;
- clock-latency-ns = <200000>;
- };
- opp-2150400000 {
- opp-hz = /bits/ 64 <2150400000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x31>;
- clock-latency-ns = <200000>;
- };
- opp-2246400000 {
- opp-hz = /bits/ 64 <2246400000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x10>;
- clock-latency-ns = <200000>;
- };
- opp-2342400000 {
- opp-hz = /bits/ 64 <2342400000>;
- opp-microvolt = <1140000 905000 1140000>;
- opp-supported-hw = <0x10>;
- clock-latency-ns = <200000>;
- };
- };
-
-....
-
-reserved-memory {
- #address-cells = <2>;
- #size-cells = <2>;
- ranges;
-....
- smem_mem: smem-mem@86000000 {
- reg = <0x0 0x86000000 0x0 0x200000>;
- no-map;
- };
-....
-};
-
-smem {
- compatible = "qcom,smem";
- memory-region = <&smem_mem>;
- hwlocks = <&tcsr_mutex 3>;
-};
-
-soc {
-....
- qfprom: qfprom@74000 {
- compatible = "qcom,qfprom";
- reg = <0x00074000 0x8ff>;
- #address-cells = <1>;
- #size-cells = <1>;
- ....
- speedbin_efuse: speedbin@133 {
- reg = <0x133 0x1>;
- bits = <5 3>;
- };
- };
-};
-
-Example 2:
----------
-
- cpus {
- #address-cells = <1>;
- #size-cells = <0>;
-
- CPU0: cpu@100 {
- device_type = "cpu";
- compatible = "arm,cortex-a53";
- reg = <0x100>;
- ....
- clocks = <&apcs_glb>;
- operating-points-v2 = <&cpu_opp_table>;
- power-domains = <&cpr>;
- power-domain-names = "cpr";
- };
-
- CPU1: cpu@101 {
- device_type = "cpu";
- compatible = "arm,cortex-a53";
- reg = <0x101>;
- ....
- clocks = <&apcs_glb>;
- operating-points-v2 = <&cpu_opp_table>;
- power-domains = <&cpr>;
- power-domain-names = "cpr";
- };
-
- CPU2: cpu@102 {
- device_type = "cpu";
- compatible = "arm,cortex-a53";
- reg = <0x102>;
- ....
- clocks = <&apcs_glb>;
- operating-points-v2 = <&cpu_opp_table>;
- power-domains = <&cpr>;
- power-domain-names = "cpr";
- };
-
- CPU3: cpu@103 {
- device_type = "cpu";
- compatible = "arm,cortex-a53";
- reg = <0x103>;
- ....
- clocks = <&apcs_glb>;
- operating-points-v2 = <&cpu_opp_table>;
- power-domains = <&cpr>;
- power-domain-names = "cpr";
- };
- };
-
- cpu_opp_table: cpu-opp-table {
- compatible = "operating-points-v2-kryo-cpu";
- opp-shared;
-
- opp-1094400000 {
- opp-hz = /bits/ 64 <1094400000>;
- required-opps = <&cpr_opp1>;
- };
- opp-1248000000 {
- opp-hz = /bits/ 64 <1248000000>;
- required-opps = <&cpr_opp2>;
- };
- opp-1401600000 {
- opp-hz = /bits/ 64 <1401600000>;
- required-opps = <&cpr_opp3>;
- };
- };
-
- cpr_opp_table: cpr-opp-table {
- compatible = "operating-points-v2-qcom-level";
-
- cpr_opp1: opp1 {
- opp-level = <1>;
- qcom,opp-fuse-level = <1>;
- };
- cpr_opp2: opp2 {
- opp-level = <2>;
- qcom,opp-fuse-level = <2>;
- };
- cpr_opp3: opp3 {
- opp-level = <3>;
- qcom,opp-fuse-level = <3>;
- };
- };
-
-....
-
-soc {
-....
- cpr: power-controller@b018000 {
- compatible = "qcom,qcs404-cpr", "qcom,cpr";
- reg = <0x0b018000 0x1000>;
- ....
- vdd-apc-supply = <&pms405_s3>;
- #power-domain-cells = <0>;
- operating-points-v2 = <&cpr_opp_table>;
- ....
- };
-};
diff --git a/Documentation/devicetree/bindings/opp/qcom-opp.txt b/Documentation/devicetree/bindings/opp/qcom-opp.txt
deleted file mode 100644
index 41d3e4ff2dc3..000000000000
--- a/Documentation/devicetree/bindings/opp/qcom-opp.txt
+++ /dev/null
@@ -1,19 +0,0 @@
-Qualcomm OPP bindings to describe OPP nodes
-
-The bindings are based on top of the operating-points-v2 bindings
-described in Documentation/devicetree/bindings/opp/opp-v2-base.yaml
-Additional properties are described below.
-
-* OPP Table Node
-
-Required properties:
-- compatible: Allow OPPs to express their compatibility. It should be:
- "operating-points-v2-qcom-level"
-
-* OPP Node
-
-Required properties:
-- qcom,opp-fuse-level: A positive value representing the fuse corner/level
- associated with this OPP node. Sometimes several corners/levels shares
- a certain fuse corner/level. A fuse corner/level contains e.g. ref uV,
- min uV, and max uV.
diff --git a/Documentation/devicetree/bindings/power/avs/qcom,cpr.txt b/Documentation/devicetree/bindings/power/avs/qcom,cpr.txt
deleted file mode 100644
index ab0d5ebbad4e..000000000000
--- a/Documentation/devicetree/bindings/power/avs/qcom,cpr.txt
+++ /dev/null
@@ -1,130 +0,0 @@
-QCOM CPR (Core Power Reduction)
-
-CPR (Core Power Reduction) is a technology to reduce core power on a CPU
-or other device. Each OPP of a device corresponds to a "corner" that has
-a range of valid voltages for a particular frequency. While the device is
-running at a particular frequency, CPR monitors dynamic factors such as
-temperature, etc. and suggests adjustments to the voltage to save power
-and meet silicon characteristic requirements.
-
-- compatible:
- Usage: required
- Value type: <string>
- Definition: should be "qcom,qcs404-cpr", "qcom,cpr" for qcs404
-
-- reg:
- Usage: required
- Value type: <prop-encoded-array>
- Definition: base address and size of the rbcpr register region
-
-- interrupts:
- Usage: required
- Value type: <prop-encoded-array>
- Definition: should specify the CPR interrupt
-
-- clocks:
- Usage: required
- Value type: <prop-encoded-array>
- Definition: phandle to the reference clock
-
-- clock-names:
- Usage: required
- Value type: <stringlist>
- Definition: must be "ref"
-
-- vdd-apc-supply:
- Usage: required
- Value type: <phandle>
- Definition: phandle to the vdd-apc-supply regulator
-
-- #power-domain-cells:
- Usage: required
- Value type: <u32>
- Definition: should be 0
-
-- operating-points-v2:
- Usage: required
- Value type: <phandle>
- Definition: A phandle to the OPP table containing the
- performance states supported by the CPR
- power domain
-
-- acc-syscon:
- Usage: optional
- Value type: <phandle>
- Definition: phandle to syscon for writing ACC settings
-
-- nvmem-cells:
- Usage: required
- Value type: <phandle>
- Definition: phandle to nvmem cells containing the data
- that makes up a fuse corner, for each fuse corner.
- As well as the CPR fuse revision.
-
-- nvmem-cell-names:
- Usage: required
- Value type: <stringlist>
- Definition: should be "cpr_quotient_offset1", "cpr_quotient_offset2",
- "cpr_quotient_offset3", "cpr_init_voltage1",
- "cpr_init_voltage2", "cpr_init_voltage3", "cpr_quotient1",
- "cpr_quotient2", "cpr_quotient3", "cpr_ring_osc1",
- "cpr_ring_osc2", "cpr_ring_osc3", "cpr_fuse_revision"
- for qcs404.
-
-Example:
-
- cpr_opp_table: cpr-opp-table {
- compatible = "operating-points-v2-qcom-level";
-
- cpr_opp1: opp1 {
- opp-level = <1>;
- qcom,opp-fuse-level = <1>;
- };
- cpr_opp2: opp2 {
- opp-level = <2>;
- qcom,opp-fuse-level = <2>;
- };
- cpr_opp3: opp3 {
- opp-level = <3>;
- qcom,opp-fuse-level = <3>;
- };
- };
-
- power-controller@b018000 {
- compatible = "qcom,qcs404-cpr", "qcom,cpr";
- reg = <0x0b018000 0x1000>;
- interrupts = <0 15 IRQ_TYPE_EDGE_RISING>;
- clocks = <&xo_board>;
- clock-names = "ref";
- vdd-apc-supply = <&pms405_s3>;
- #power-domain-cells = <0>;
- operating-points-v2 = <&cpr_opp_table>;
- acc-syscon = <&tcsr>;
-
- nvmem-cells = <&cpr_efuse_quot_offset1>,
- <&cpr_efuse_quot_offset2>,
- <&cpr_efuse_quot_offset3>,
- <&cpr_efuse_init_voltage1>,
- <&cpr_efuse_init_voltage2>,
- <&cpr_efuse_init_voltage3>,
- <&cpr_efuse_quot1>,
- <&cpr_efuse_quot2>,
- <&cpr_efuse_quot3>,
- <&cpr_efuse_ring1>,
- <&cpr_efuse_ring2>,
- <&cpr_efuse_ring3>,
- <&cpr_efuse_revision>;
- nvmem-cell-names = "cpr_quotient_offset1",
- "cpr_quotient_offset2",
- "cpr_quotient_offset3",
- "cpr_init_voltage1",
- "cpr_init_voltage2",
- "cpr_init_voltage3",
- "cpr_quotient1",
- "cpr_quotient2",
- "cpr_quotient3",
- "cpr_ring_osc1",
- "cpr_ring_osc2",
- "cpr_ring_osc3",
- "cpr_fuse_revision";
- };
diff --git a/Documentation/devicetree/bindings/power/avs/qcom,cpr.yaml b/Documentation/devicetree/bindings/power/avs/qcom,cpr.yaml
new file mode 100644
index 000000000000..3301fa0c2653
--- /dev/null
+++ b/Documentation/devicetree/bindings/power/avs/qcom,cpr.yaml
@@ -0,0 +1,160 @@
+# SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause)
+%YAML 1.2
+---
+$id: http://devicetree.org/schemas/power/avs/qcom,cpr.yaml#
+$schema: http://devicetree.org/meta-schemas/core.yaml#
+
+title: Qualcomm Core Power Reduction (CPR) bindings
+
+maintainers:
+ - Niklas Cassel <nks@flawful.org>
+
+description: |
+ CPR (Core Power Reduction) is a technology to reduce core power on a CPU
+ or other device. Each OPP of a device corresponds to a "corner" that has
+ a range of valid voltages for a particular frequency. While the device is
+ running at a particular frequency, CPR monitors dynamic factors such as
+ temperature, etc. and suggests adjustments to the voltage to save power
+ and meet silicon characteristic requirements.
+
+properties:
+ compatible:
+ items:
+ - enum:
+ - qcom,qcs404-cpr
+ - const: qcom,cpr
+
+ reg:
+ description: Base address and size of the RBCPR register region.
+ maxItems: 1
+
+ interrupts:
+ maxItems: 1
+
+ clocks:
+ items:
+ - description: Reference clock.
+
+ clock-names:
+ items:
+ - const: ref
+
+ vdd-apc-supply:
+ description: APC regulator supply.
+
+ '#power-domain-cells':
+ const: 0
+
+ operating-points-v2:
+ description: |
+ A phandle to the OPP table containing the performance states
+ supported by the CPR power domain.
+
+ acc-syscon:
+ description: A phandle to the syscon used for writing ACC settings.
+
+ nvmem-cells:
+ items:
+ - description: Corner 1 quotient offset
+ - description: Corner 2 quotient offset
+ - description: Corner 3 quotient offset
+ - description: Corner 1 initial voltage
+ - description: Corner 2 initial voltage
+ - description: Corner 3 initial voltage
+ - description: Corner 1 quotient
+ - description: Corner 2 quotient
+ - description: Corner 3 quotient
+ - description: Corner 1 ring oscillator
+ - description: Corner 2 ring oscillator
+ - description: Corner 3 ring oscillator
+ - description: Fuse revision
+
+ nvmem-cell-names:
+ items:
+ - const: cpr_quotient_offset1
+ - const: cpr_quotient_offset2
+ - const: cpr_quotient_offset3
+ - const: cpr_init_voltage1
+ - const: cpr_init_voltage2
+ - const: cpr_init_voltage3
+ - const: cpr_quotient1
+ - const: cpr_quotient2
+ - const: cpr_quotient3
+ - const: cpr_ring_osc1
+ - const: cpr_ring_osc2
+ - const: cpr_ring_osc3
+ - const: cpr_fuse_revision
+
+required:
+ - compatible
+ - reg
+ - interrupts
+ - clocks
+ - clock-names
+ - vdd-apc-supply
+ - '#power-domain-cells'
+ - operating-points-v2
+ - nvmem-cells
+ - nvmem-cell-names
+
+additionalProperties: false
+
+examples:
+ - |
+ #include <dt-bindings/interrupt-controller/arm-gic.h>
+
+ cpr_opp_table: opp-table-cpr {
+ compatible = "operating-points-v2-qcom-level";
+
+ cpr_opp1: opp1 {
+ opp-level = <1>;
+ qcom,opp-fuse-level = <1>;
+ };
+ cpr_opp2: opp2 {
+ opp-level = <2>;
+ qcom,opp-fuse-level = <2>;
+ };
+ cpr_opp3: opp3 {
+ opp-level = <3>;
+ qcom,opp-fuse-level = <3>;
+ };
+ };
+
+ power-controller@b018000 {
+ compatible = "qcom,qcs404-cpr", "qcom,cpr";
+ reg = <0x0b018000 0x1000>;
+ interrupts = <0 15 IRQ_TYPE_EDGE_RISING>;
+ clocks = <&xo_board>;
+ clock-names = "ref";
+ vdd-apc-supply = <&pms405_s3>;
+ #power-domain-cells = <0>;
+ operating-points-v2 = <&cpr_opp_table>;
+ acc-syscon = <&tcsr>;
+
+ nvmem-cells = <&cpr_efuse_quot_offset1>,
+ <&cpr_efuse_quot_offset2>,
+ <&cpr_efuse_quot_offset3>,
+ <&cpr_efuse_init_voltage1>,
+ <&cpr_efuse_init_voltage2>,
+ <&cpr_efuse_init_voltage3>,
+ <&cpr_efuse_quot1>,
+ <&cpr_efuse_quot2>,
+ <&cpr_efuse_quot3>,
+ <&cpr_efuse_ring1>,
+ <&cpr_efuse_ring2>,
+ <&cpr_efuse_ring3>,
+ <&cpr_efuse_revision>;
+ nvmem-cell-names = "cpr_quotient_offset1",
+ "cpr_quotient_offset2",
+ "cpr_quotient_offset3",
+ "cpr_init_voltage1",
+ "cpr_init_voltage2",
+ "cpr_init_voltage3",
+ "cpr_quotient1",
+ "cpr_quotient2",
+ "cpr_quotient3",
+ "cpr_ring_osc1",
+ "cpr_ring_osc2",
+ "cpr_ring_osc3",
+ "cpr_fuse_revision";
+ };
diff --git a/Documentation/power/energy-model.rst b/Documentation/power/energy-model.rst
index 5ac62a7b4b7c..49549aab41b4 100644
--- a/Documentation/power/energy-model.rst
+++ b/Documentation/power/energy-model.rst
@@ -113,6 +113,16 @@ to: return warning/error, stop working or panic.
See Section 3. for an example of driver implementing this
callback, or Section 2.4 for further documentation on this API
+Registration of EM using DT
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+The EM can also be registered using OPP framework and information in DT
+"operating-points-v2". Each OPP entry in DT can be extended with a property
+"opp-microwatt" containing micro-Watts power value. This OPP DT property
+allows a platform to register EM power values which are reflecting total power
+(static + dynamic). These power values might be coming directly from
+experiments and measurements.
+
Registration of 'simple' EM
~~~~~~~~~~~~~~~~~~~~~~~~~~~