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author | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-05-06 01:02:30 +0000 |
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committer | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-05-06 01:02:30 +0000 |
commit | 76cb841cb886eef6b3bee341a2266c76578724ad (patch) | |
tree | f5892e5ba6cc11949952a6ce4ecbe6d516d6ce58 /Documentation/acpi | |
parent | Initial commit. (diff) | |
download | linux-76cb841cb886eef6b3bee341a2266c76578724ad.tar.xz linux-76cb841cb886eef6b3bee341a2266c76578724ad.zip |
Adding upstream version 4.19.249.upstream/4.19.249upstream
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to 'Documentation/acpi')
23 files changed, 3366 insertions, 0 deletions
diff --git a/Documentation/acpi/DSD-properties-rules.txt b/Documentation/acpi/DSD-properties-rules.txt new file mode 100644 index 000000000..3e4862bda --- /dev/null +++ b/Documentation/acpi/DSD-properties-rules.txt @@ -0,0 +1,97 @@ +_DSD Device Properties Usage Rules +---------------------------------- + +Properties, Property Sets and Property Subsets +---------------------------------------------- + +The _DSD (Device Specific Data) configuration object, introduced in ACPI 5.1, +allows any type of device configuration data to be provided via the ACPI +namespace. In principle, the format of the data may be arbitrary, but it has to +be identified by a UUID which must be recognized by the driver processing the +_DSD output. However, there are generic UUIDs defined for _DSD recognized by +the ACPI subsystem in the Linux kernel which automatically processes the data +packages associated with them and makes those data available to device drivers +as "device properties". + +A device property is a data item consisting of a string key and a value (of a +specific type) associated with it. + +In the ACPI _DSD context it is an element of the sub-package following the +generic Device Properties UUID in the _DSD return package as specified in the +Device Properties UUID definition document [1]. + +It also may be regarded as the definition of a key and the associated data type +that can be returned by _DSD in the Device Properties UUID sub-package for a +given device. + +A property set is a collection of properties applicable to a hardware entity +like a device. In the ACPI _DSD context it is the set of all properties that +can be returned in the Device Properties UUID sub-package for the device in +question. + +Property subsets are nested collections of properties. Each of them is +associated with an additional key (name) allowing the subset to be referred +to as a whole (and to be treated as a separate entity). The canonical +representation of property subsets is via the mechanism specified in the +Hierarchical Properties Extension UUID definition document [2]. + +Property sets may be hierarchical. That is, a property set may contain +multiple property subsets that each may contain property subsets of its +own and so on. + +General Validity Rule for Property Sets +--------------------------------------- + +Valid property sets must follow the guidance given by the Device Properties UUID +definition document [1]. + +_DSD properties are intended to be used in addition to, and not instead of, the +existing mechanisms defined by the ACPI specification. Therefore, as a rule, +they should only be used if the ACPI specification does not make direct +provisions for handling the underlying use case. It generally is invalid to +return property sets which do not follow that rule from _DSD in data packages +associated with the Device Properties UUID. + +Additional Considerations +------------------------- + +There are cases in which, even if the general rule given above is followed in +principle, the property set may still not be regarded as a valid one. + +For example, that applies to device properties which may cause kernel code +(either a device driver or a library/subsystem) to access hardware in a way +possibly leading to a conflict with AML methods in the ACPI namespace. In +particular, that may happen if the kernel code uses device properties to +manipulate hardware normally controlled by ACPI methods related to power +management, like _PSx and _DSW (for device objects) or _ON and _OFF (for power +resource objects), or by ACPI device disabling/enabling methods, like _DIS and +_SRS. + +In all cases in which kernel code may do something that will confuse AML as a +result of using device properties, the device properties in question are not +suitable for the ACPI environment and consequently they cannot belong to a valid +property set. + +Property Sets and Device Tree Bindings +-------------------------------------- + +It often is useful to make _DSD return property sets that follow Device Tree +bindings. + +In those cases, however, the above validity considerations must be taken into +account in the first place and returning invalid property sets from _DSD must be +avoided. For this reason, it may not be possible to make _DSD return a property +set following the given DT binding literally and completely. Still, for the +sake of code re-use, it may make sense to provide as much of the configuration +data as possible in the form of device properties and complement that with an +ACPI-specific mechanism suitable for the use case at hand. + +In any case, property sets following DT bindings literally should not be +expected to automatically work in the ACPI environment regardless of their +contents. + +References +---------- + +[1] http://www.uefi.org/sites/default/files/resources/_DSD-device-properties-UUID.pdf +[2] http://www.uefi.org/sites/default/files/resources/_DSD-hierarchical-data-extension-UUID-v1.1.pdf diff --git a/Documentation/acpi/acpi-lid.txt b/Documentation/acpi/acpi-lid.txt new file mode 100644 index 000000000..effe7af3a --- /dev/null +++ b/Documentation/acpi/acpi-lid.txt @@ -0,0 +1,96 @@ +Special Usage Model of the ACPI Control Method Lid Device + +Copyright (C) 2016, Intel Corporation +Author: Lv Zheng <lv.zheng@intel.com> + + +Abstract: + +Platforms containing lids convey lid state (open/close) to OSPMs using a +control method lid device. To implement this, the AML tables issue +Notify(lid_device, 0x80) to notify the OSPMs whenever the lid state has +changed. The _LID control method for the lid device must be implemented to +report the "current" state of the lid as either "opened" or "closed". + +For most platforms, both the _LID method and the lid notifications are +reliable. However, there are exceptions. In order to work with these +exceptional buggy platforms, special restrictions and expections should be +taken into account. This document describes the restrictions and the +expections of the Linux ACPI lid device driver. + + +1. Restrictions of the returning value of the _LID control method + +The _LID control method is described to return the "current" lid state. +However the word of "current" has ambiguity, some buggy AML tables return +the lid state upon the last lid notification instead of returning the lid +state upon the last _LID evaluation. There won't be difference when the +_LID control method is evaluated during the runtime, the problem is its +initial returning value. When the AML tables implement this control method +with cached value, the initial returning value is likely not reliable. +There are platforms always retun "closed" as initial lid state. + +2. Restrictions of the lid state change notifications + +There are buggy AML tables never notifying when the lid device state is +changed to "opened". Thus the "opened" notification is not guaranteed. But +it is guaranteed that the AML tables always notify "closed" when the lid +state is changed to "closed". The "closed" notification is normally used to +trigger some system power saving operations on Windows. Since it is fully +tested, it is reliable from all AML tables. + +3. Expections for the userspace users of the ACPI lid device driver + +The ACPI button driver exports the lid state to the userspace via the +following file: + /proc/acpi/button/lid/LID0/state +This file actually calls the _LID control method described above. And given +the previous explanation, it is not reliable enough on some platforms. So +it is advised for the userspace program to not to solely rely on this file +to determine the actual lid state. + +The ACPI button driver emits the following input event to the userspace: + SW_LID +The ACPI lid device driver is implemented to try to deliver the platform +triggered events to the userspace. However, given the fact that the buggy +firmware cannot make sure "opened"/"closed" events are paired, the ACPI +button driver uses the following 3 modes in order not to trigger issues. + +If the userspace hasn't been prepared to ignore the unreliable "opened" +events and the unreliable initial state notification, Linux users can use +the following kernel parameters to handle the possible issues: +A. button.lid_init_state=method: + When this option is specified, the ACPI button driver reports the + initial lid state using the returning value of the _LID control method + and whether the "opened"/"closed" events are paired fully relies on the + firmware implementation. + This option can be used to fix some platforms where the returning value + of the _LID control method is reliable but the initial lid state + notification is missing. + This option is the default behavior during the period the userspace + isn't ready to handle the buggy AML tables. +B. button.lid_init_state=open: + When this option is specified, the ACPI button driver always reports the + initial lid state as "opened" and whether the "opened"/"closed" events + are paired fully relies on the firmware implementation. + This may fix some platforms where the returning value of the _LID + control method is not reliable and the initial lid state notification is + missing. + +If the userspace has been prepared to ignore the unreliable "opened" events +and the unreliable initial state notification, Linux users should always +use the following kernel parameter: +C. button.lid_init_state=ignore: + When this option is specified, the ACPI button driver never reports the + initial lid state and there is a compensation mechanism implemented to + ensure that the reliable "closed" notifications can always be delievered + to the userspace by always pairing "closed" input events with complement + "opened" input events. But there is still no guarantee that the "opened" + notifications can be delivered to the userspace when the lid is actually + opens given that some AML tables do not send "opened" notifications + reliably. + In this mode, if everything is correctly implemented by the platform + firmware, the old userspace programs should still work. Otherwise, the + new userspace programs are required to work with the ACPI button driver. + This option will be the default behavior after the userspace is ready to + handle the buggy AML tables. diff --git a/Documentation/acpi/aml-debugger.txt b/Documentation/acpi/aml-debugger.txt new file mode 100644 index 000000000..e851cc5de --- /dev/null +++ b/Documentation/acpi/aml-debugger.txt @@ -0,0 +1,66 @@ +The AML Debugger + +Copyright (C) 2016, Intel Corporation +Author: Lv Zheng <lv.zheng@intel.com> + + +This document describes the usage of the AML debugger embedded in the Linux +kernel. + +1. Build the debugger + + The following kernel configuration items are required to enable the AML + debugger interface from the Linux kernel: + + CONFIG_ACPI_DEBUGGER=y + CONFIG_ACPI_DEBUGGER_USER=m + + The userspace utilities can be built from the kernel source tree using + the following commands: + + $ cd tools + $ make acpi + + The resultant userspace tool binary is then located at: + + tools/acpi/power/acpi/acpidbg/acpidbg + + It can be installed to system directories by running "make install" (as a + sufficiently privileged user). + +2. Start the userspace debugger interface + + After booting the kernel with the debugger built-in, the debugger can be + started by using the following commands: + + # mount -t debugfs none /sys/kernel/debug + # modprobe acpi_dbg + # tools/acpi/power/acpi/acpidbg/acpidbg + + That spawns the interactive AML debugger environment where you can execute + debugger commands. + + The commands are documented in the "ACPICA Overview and Programmer Reference" + that can be downloaded from + + https://acpica.org/documentation + + The detailed debugger commands reference is located in Chapter 12 "ACPICA + Debugger Reference". The "help" command can be used for a quick reference. + +3. Stop the userspace debugger interface + + The interactive debugger interface can be closed by pressing Ctrl+C or using + the "quit" or "exit" commands. When finished, unload the module with: + + # rmmod acpi_dbg + + The module unloading may fail if there is an acpidbg instance running. + +4. Run the debugger in a script + + It may be useful to run the AML debugger in a test script. "acpidbg" supports + this in a special "batch" mode. For example, the following command outputs + the entire ACPI namespace: + + # acpidbg -b "namespace" diff --git a/Documentation/acpi/apei/einj.txt b/Documentation/acpi/apei/einj.txt new file mode 100644 index 000000000..e550c8b98 --- /dev/null +++ b/Documentation/acpi/apei/einj.txt @@ -0,0 +1,177 @@ + APEI Error INJection + ~~~~~~~~~~~~~~~~~~~~ + +EINJ provides a hardware error injection mechanism. It is very useful +for debugging and testing APEI and RAS features in general. + +You need to check whether your BIOS supports EINJ first. For that, look +for early boot messages similar to this one: + +ACPI: EINJ 0x000000007370A000 000150 (v01 INTEL 00000001 INTL 00000001) + +which shows that the BIOS is exposing an EINJ table - it is the +mechanism through which the injection is done. + +Alternatively, look in /sys/firmware/acpi/tables for an "EINJ" file, +which is a different representation of the same thing. + +It doesn't necessarily mean that EINJ is not supported if those above +don't exist: before you give up, go into BIOS setup to see if the BIOS +has an option to enable error injection. Look for something called WHEA +or similar. Often, you need to enable an ACPI5 support option prior, in +order to see the APEI,EINJ,... functionality supported and exposed by +the BIOS menu. + +To use EINJ, make sure the following are options enabled in your kernel +configuration: + +CONFIG_DEBUG_FS +CONFIG_ACPI_APEI +CONFIG_ACPI_APEI_EINJ + +The EINJ user interface is in <debugfs mount point>/apei/einj. + +The following files belong to it: + +- available_error_type + + This file shows which error types are supported: + + Error Type Value Error Description + ================ ================= + 0x00000001 Processor Correctable + 0x00000002 Processor Uncorrectable non-fatal + 0x00000004 Processor Uncorrectable fatal + 0x00000008 Memory Correctable + 0x00000010 Memory Uncorrectable non-fatal + 0x00000020 Memory Uncorrectable fatal + 0x00000040 PCI Express Correctable + 0x00000080 PCI Express Uncorrectable fatal + 0x00000100 PCI Express Uncorrectable non-fatal + 0x00000200 Platform Correctable + 0x00000400 Platform Uncorrectable non-fatal + 0x00000800 Platform Uncorrectable fatal + + The format of the file contents are as above, except present are only + the available error types. + +- error_type + + Set the value of the error type being injected. Possible error types + are defined in the file available_error_type above. + +- error_inject + + Write any integer to this file to trigger the error injection. Make + sure you have specified all necessary error parameters, i.e. this + write should be the last step when injecting errors. + +- flags + + Present for kernel versions 3.13 and above. Used to specify which + of param{1..4} are valid and should be used by the firmware during + injection. Value is a bitmask as specified in ACPI5.0 spec for the + SET_ERROR_TYPE_WITH_ADDRESS data structure: + + Bit 0 - Processor APIC field valid (see param3 below). + Bit 1 - Memory address and mask valid (param1 and param2). + Bit 2 - PCIe (seg,bus,dev,fn) valid (see param4 below). + + If set to zero, legacy behavior is mimicked where the type of + injection specifies just one bit set, and param1 is multiplexed. + +- param1 + + This file is used to set the first error parameter value. Its effect + depends on the error type specified in error_type. For example, if + error type is memory related type, the param1 should be a valid + physical memory address. [Unless "flag" is set - see above] + +- param2 + + Same use as param1 above. For example, if error type is of memory + related type, then param2 should be a physical memory address mask. + Linux requires page or narrower granularity, say, 0xfffffffffffff000. + +- param3 + + Used when the 0x1 bit is set in "flags" to specify the APIC id + +- param4 + Used when the 0x4 bit is set in "flags" to specify target PCIe device + +- notrigger + + The error injection mechanism is a two-step process. First inject the + error, then perform some actions to trigger it. Setting "notrigger" + to 1 skips the trigger phase, which *may* allow the user to cause the + error in some other context by a simple access to the CPU, memory + location, or device that is the target of the error injection. Whether + this actually works depends on what operations the BIOS actually + includes in the trigger phase. + +BIOS versions based on the ACPI 4.0 specification have limited options +in controlling where the errors are injected. Your BIOS may support an +extension (enabled with the param_extension=1 module parameter, or boot +command line einj.param_extension=1). This allows the address and mask +for memory injections to be specified by the param1 and param2 files in +apei/einj. + +BIOS versions based on the ACPI 5.0 specification have more control over +the target of the injection. For processor-related errors (type 0x1, 0x2 +and 0x4), you can set flags to 0x3 (param3 for bit 0, and param1 and +param2 for bit 1) so that you have more information added to the error +signature being injected. The actual data passed is this: + + memory_address = param1; + memory_address_range = param2; + apicid = param3; + pcie_sbdf = param4; + +For memory errors (type 0x8, 0x10 and 0x20) the address is set using +param1 with a mask in param2 (0x0 is equivalent to all ones). For PCI +express errors (type 0x40, 0x80 and 0x100) the segment, bus, device and +function are specified using param1: + + 31 24 23 16 15 11 10 8 7 0 + +-------------------------------------------------+ + | segment | bus | device | function | reserved | + +-------------------------------------------------+ + +Anyway, you get the idea, if there's doubt just take a look at the code +in drivers/acpi/apei/einj.c. + +An ACPI 5.0 BIOS may also allow vendor-specific errors to be injected. +In this case a file named vendor will contain identifying information +from the BIOS that hopefully will allow an application wishing to use +the vendor-specific extension to tell that they are running on a BIOS +that supports it. All vendor extensions have the 0x80000000 bit set in +error_type. A file vendor_flags controls the interpretation of param1 +and param2 (1 = PROCESSOR, 2 = MEMORY, 4 = PCI). See your BIOS vendor +documentation for details (and expect changes to this API if vendors +creativity in using this feature expands beyond our expectations). + + +An error injection example: + +# cd /sys/kernel/debug/apei/einj +# cat available_error_type # See which errors can be injected +0x00000002 Processor Uncorrectable non-fatal +0x00000008 Memory Correctable +0x00000010 Memory Uncorrectable non-fatal +# echo 0x12345000 > param1 # Set memory address for injection +# echo $((-1 << 12)) > param2 # Mask 0xfffffffffffff000 - anywhere in this page +# echo 0x8 > error_type # Choose correctable memory error +# echo 1 > error_inject # Inject now + +You should see something like this in dmesg: + +[22715.830801] EDAC sbridge MC3: HANDLING MCE MEMORY ERROR +[22715.834759] EDAC sbridge MC3: CPU 0: Machine Check Event: 0 Bank 7: 8c00004000010090 +[22715.834759] EDAC sbridge MC3: TSC 0 +[22715.834759] EDAC sbridge MC3: ADDR 12345000 EDAC sbridge MC3: MISC 144780c86 +[22715.834759] EDAC sbridge MC3: PROCESSOR 0:306e7 TIME 1422553404 SOCKET 0 APIC 0 +[22716.616173] EDAC MC3: 1 CE memory read error on CPU_SrcID#0_Channel#0_DIMM#0 (channel:0 slot:0 page:0x12345 offset:0x0 grain:32 syndrome:0x0 - area:DRAM err_code:0001:0090 socket:0 channel_mask:1 rank:0) + +For more information about EINJ, please refer to ACPI specification +version 4.0, section 17.5 and ACPI 5.0, section 18.6. diff --git a/Documentation/acpi/apei/output_format.txt b/Documentation/acpi/apei/output_format.txt new file mode 100644 index 000000000..0c49c197c --- /dev/null +++ b/Documentation/acpi/apei/output_format.txt @@ -0,0 +1,147 @@ + APEI output format + ~~~~~~~~~~~~~~~~~~ + +APEI uses printk as hardware error reporting interface, the output +format is as follow. + +<error record> := +APEI generic hardware error status +severity: <integer>, <severity string> +section: <integer>, severity: <integer>, <severity string> +flags: <integer> +<section flags strings> +fru_id: <uuid string> +fru_text: <string> +section_type: <section type string> +<section data> + +<severity string>* := recoverable | fatal | corrected | info + +<section flags strings># := +[primary][, containment warning][, reset][, threshold exceeded]\ +[, resource not accessible][, latent error] + +<section type string> := generic processor error | memory error | \ +PCIe error | unknown, <uuid string> + +<section data> := +<generic processor section data> | <memory section data> | \ +<pcie section data> | <null> + +<generic processor section data> := +[processor_type: <integer>, <proc type string>] +[processor_isa: <integer>, <proc isa string>] +[error_type: <integer> +<proc error type strings>] +[operation: <integer>, <proc operation string>] +[flags: <integer> +<proc flags strings>] +[level: <integer>] +[version_info: <integer>] +[processor_id: <integer>] +[target_address: <integer>] +[requestor_id: <integer>] +[responder_id: <integer>] +[IP: <integer>] + +<proc type string>* := IA32/X64 | IA64 + +<proc isa string>* := IA32 | IA64 | X64 + +<processor error type strings># := +[cache error][, TLB error][, bus error][, micro-architectural error] + +<proc operation string>* := unknown or generic | data read | data write | \ +instruction execution + +<proc flags strings># := +[restartable][, precise IP][, overflow][, corrected] + +<memory section data> := +[error_status: <integer>] +[physical_address: <integer>] +[physical_address_mask: <integer>] +[node: <integer>] +[card: <integer>] +[module: <integer>] +[bank: <integer>] +[device: <integer>] +[row: <integer>] +[column: <integer>] +[bit_position: <integer>] +[requestor_id: <integer>] +[responder_id: <integer>] +[target_id: <integer>] +[error_type: <integer>, <mem error type string>] + +<mem error type string>* := +unknown | no error | single-bit ECC | multi-bit ECC | \ +single-symbol chipkill ECC | multi-symbol chipkill ECC | master abort | \ +target abort | parity error | watchdog timeout | invalid address | \ +mirror Broken | memory sparing | scrub corrected error | \ +scrub uncorrected error + +<pcie section data> := +[port_type: <integer>, <pcie port type string>] +[version: <integer>.<integer>] +[command: <integer>, status: <integer>] +[device_id: <integer>:<integer>:<integer>.<integer> +slot: <integer> +secondary_bus: <integer> +vendor_id: <integer>, device_id: <integer> +class_code: <integer>] +[serial number: <integer>, <integer>] +[bridge: secondary_status: <integer>, control: <integer>] +[aer_status: <integer>, aer_mask: <integer> +<aer status string> +[aer_uncor_severity: <integer>] +aer_layer=<aer layer string>, aer_agent=<aer agent string> +aer_tlp_header: <integer> <integer> <integer> <integer>] + +<pcie port type string>* := PCIe end point | legacy PCI end point | \ +unknown | unknown | root port | upstream switch port | \ +downstream switch port | PCIe to PCI/PCI-X bridge | \ +PCI/PCI-X to PCIe bridge | root complex integrated endpoint device | \ +root complex event collector + +if section severity is fatal or recoverable +<aer status string># := +unknown | unknown | unknown | unknown | Data Link Protocol | \ +unknown | unknown | unknown | unknown | unknown | unknown | unknown | \ +Poisoned TLP | Flow Control Protocol | Completion Timeout | \ +Completer Abort | Unexpected Completion | Receiver Overflow | \ +Malformed TLP | ECRC | Unsupported Request +else +<aer status string># := +Receiver Error | unknown | unknown | unknown | unknown | unknown | \ +Bad TLP | Bad DLLP | RELAY_NUM Rollover | unknown | unknown | unknown | \ +Replay Timer Timeout | Advisory Non-Fatal +fi + +<aer layer string> := +Physical Layer | Data Link Layer | Transaction Layer + +<aer agent string> := +Receiver ID | Requester ID | Completer ID | Transmitter ID + +Where, [] designate corresponding content is optional + +All <field string> description with * has the following format: + +field: <integer>, <field string> + +Where value of <integer> should be the position of "string" in <field +string> description. Otherwise, <field string> will be "unknown". + +All <field strings> description with # has the following format: + +field: <integer> +<field strings> + +Where each string in <fields strings> corresponding to one set bit of +<integer>. The bit position is the position of "string" in <field +strings> description. + +For more detailed explanation of every field, please refer to UEFI +specification version 2.3 or later, section Appendix N: Common +Platform Error Record. diff --git a/Documentation/acpi/cppc_sysfs.txt b/Documentation/acpi/cppc_sysfs.txt new file mode 100644 index 000000000..f20fb4451 --- /dev/null +++ b/Documentation/acpi/cppc_sysfs.txt @@ -0,0 +1,69 @@ + + Collaborative Processor Performance Control (CPPC) + +CPPC defined in the ACPI spec describes a mechanism for the OS to manage the +performance of a logical processor on a contigious and abstract performance +scale. CPPC exposes a set of registers to describe abstract performance scale, +to request performance levels and to measure per-cpu delivered performance. + +For more details on CPPC please refer to the ACPI specification at: + +http://uefi.org/specifications + +Some of the CPPC registers are exposed via sysfs under: + +/sys/devices/system/cpu/cpuX/acpi_cppc/ + +for each cpu X + +-------------------------------------------------------------------------------- + +$ ls -lR /sys/devices/system/cpu/cpu0/acpi_cppc/ +/sys/devices/system/cpu/cpu0/acpi_cppc/: +total 0 +-r--r--r-- 1 root root 65536 Mar 5 19:38 feedback_ctrs +-r--r--r-- 1 root root 65536 Mar 5 19:38 highest_perf +-r--r--r-- 1 root root 65536 Mar 5 19:38 lowest_freq +-r--r--r-- 1 root root 65536 Mar 5 19:38 lowest_nonlinear_perf +-r--r--r-- 1 root root 65536 Mar 5 19:38 lowest_perf +-r--r--r-- 1 root root 65536 Mar 5 19:38 nominal_freq +-r--r--r-- 1 root root 65536 Mar 5 19:38 nominal_perf +-r--r--r-- 1 root root 65536 Mar 5 19:38 reference_perf +-r--r--r-- 1 root root 65536 Mar 5 19:38 wraparound_time + +-------------------------------------------------------------------------------- + +* highest_perf : Highest performance of this processor (abstract scale). +* nominal_perf : Highest sustained performance of this processor (abstract scale). +* lowest_nonlinear_perf : Lowest performance of this processor with nonlinear + power savings (abstract scale). +* lowest_perf : Lowest performance of this processor (abstract scale). + +* lowest_freq : CPU frequency corresponding to lowest_perf (in MHz). +* nominal_freq : CPU frequency corresponding to nominal_perf (in MHz). + The above frequencies should only be used to report processor performance in + freqency instead of abstract scale. These values should not be used for any + functional decisions. + +* feedback_ctrs : Includes both Reference and delivered performance counter. + Reference counter ticks up proportional to processor's reference performance. + Delivered counter ticks up proportional to processor's delivered performance. +* wraparound_time: Minimum time for the feedback counters to wraparound (seconds). +* reference_perf : Performance level at which reference performance counter + accumulates (abstract scale). + +-------------------------------------------------------------------------------- + + Computing Average Delivered Performance + +Below describes the steps to compute the average performance delivered by taking +two different snapshots of feedback counters at time T1 and T2. + +T1: Read feedback_ctrs as fbc_t1 + Wait or run some workload +T2: Read feedback_ctrs as fbc_t2 + +delivered_counter_delta = fbc_t2[del] - fbc_t1[del] +reference_counter_delta = fbc_t2[ref] - fbc_t1[ref] + +delivered_perf = (refernce_perf x delivered_counter_delta) / reference_counter_delta diff --git a/Documentation/acpi/debug.txt b/Documentation/acpi/debug.txt new file mode 100644 index 000000000..65bf47c46 --- /dev/null +++ b/Documentation/acpi/debug.txt @@ -0,0 +1,148 @@ + ACPI Debug Output + + +The ACPI CA, the Linux ACPI core, and some ACPI drivers can generate debug +output. This document describes how to use this facility. + +Compile-time configuration +-------------------------- + +ACPI debug output is globally enabled by CONFIG_ACPI_DEBUG. If this config +option is turned off, the debug messages are not even built into the +kernel. + +Boot- and run-time configuration +-------------------------------- + +When CONFIG_ACPI_DEBUG=y, you can select the component and level of messages +you're interested in. At boot-time, use the acpi.debug_layer and +acpi.debug_level kernel command line options. After boot, you can use the +debug_layer and debug_level files in /sys/module/acpi/parameters/ to control +the debug messages. + +debug_layer (component) +----------------------- + +The "debug_layer" is a mask that selects components of interest, e.g., a +specific driver or part of the ACPI interpreter. To build the debug_layer +bitmask, look for the "#define _COMPONENT" in an ACPI source file. + +You can set the debug_layer mask at boot-time using the acpi.debug_layer +command line argument, and you can change it after boot by writing values +to /sys/module/acpi/parameters/debug_layer. + +The possible components are defined in include/acpi/acoutput.h and +include/acpi/acpi_drivers.h. Reading /sys/module/acpi/parameters/debug_layer +shows the supported mask values, currently these: + + ACPI_UTILITIES 0x00000001 + ACPI_HARDWARE 0x00000002 + ACPI_EVENTS 0x00000004 + ACPI_TABLES 0x00000008 + ACPI_NAMESPACE 0x00000010 + ACPI_PARSER 0x00000020 + ACPI_DISPATCHER 0x00000040 + ACPI_EXECUTER 0x00000080 + ACPI_RESOURCES 0x00000100 + ACPI_CA_DEBUGGER 0x00000200 + ACPI_OS_SERVICES 0x00000400 + ACPI_CA_DISASSEMBLER 0x00000800 + ACPI_COMPILER 0x00001000 + ACPI_TOOLS 0x00002000 + ACPI_BUS_COMPONENT 0x00010000 + ACPI_AC_COMPONENT 0x00020000 + ACPI_BATTERY_COMPONENT 0x00040000 + ACPI_BUTTON_COMPONENT 0x00080000 + ACPI_SBS_COMPONENT 0x00100000 + ACPI_FAN_COMPONENT 0x00200000 + ACPI_PCI_COMPONENT 0x00400000 + ACPI_POWER_COMPONENT 0x00800000 + ACPI_CONTAINER_COMPONENT 0x01000000 + ACPI_SYSTEM_COMPONENT 0x02000000 + ACPI_THERMAL_COMPONENT 0x04000000 + ACPI_MEMORY_DEVICE_COMPONENT 0x08000000 + ACPI_VIDEO_COMPONENT 0x10000000 + ACPI_PROCESSOR_COMPONENT 0x20000000 + +debug_level +----------- + +The "debug_level" is a mask that selects different types of messages, e.g., +those related to initialization, method execution, informational messages, etc. +To build debug_level, look at the level specified in an ACPI_DEBUG_PRINT() +statement. + +The ACPI interpreter uses several different levels, but the Linux +ACPI core and ACPI drivers generally only use ACPI_LV_INFO. + +You can set the debug_level mask at boot-time using the acpi.debug_level +command line argument, and you can change it after boot by writing values +to /sys/module/acpi/parameters/debug_level. + +The possible levels are defined in include/acpi/acoutput.h. Reading +/sys/module/acpi/parameters/debug_level shows the supported mask values, +currently these: + + ACPI_LV_INIT 0x00000001 + ACPI_LV_DEBUG_OBJECT 0x00000002 + ACPI_LV_INFO 0x00000004 + ACPI_LV_INIT_NAMES 0x00000020 + ACPI_LV_PARSE 0x00000040 + ACPI_LV_LOAD 0x00000080 + ACPI_LV_DISPATCH 0x00000100 + ACPI_LV_EXEC 0x00000200 + ACPI_LV_NAMES 0x00000400 + ACPI_LV_OPREGION 0x00000800 + ACPI_LV_BFIELD 0x00001000 + ACPI_LV_TABLES 0x00002000 + ACPI_LV_VALUES 0x00004000 + ACPI_LV_OBJECTS 0x00008000 + ACPI_LV_RESOURCES 0x00010000 + ACPI_LV_USER_REQUESTS 0x00020000 + ACPI_LV_PACKAGE 0x00040000 + ACPI_LV_ALLOCATIONS 0x00100000 + ACPI_LV_FUNCTIONS 0x00200000 + ACPI_LV_OPTIMIZATIONS 0x00400000 + ACPI_LV_MUTEX 0x01000000 + ACPI_LV_THREADS 0x02000000 + ACPI_LV_IO 0x04000000 + ACPI_LV_INTERRUPTS 0x08000000 + ACPI_LV_AML_DISASSEMBLE 0x10000000 + ACPI_LV_VERBOSE_INFO 0x20000000 + ACPI_LV_FULL_TABLES 0x40000000 + ACPI_LV_EVENTS 0x80000000 + +Examples +-------- + +For example, drivers/acpi/bus.c contains this: + + #define _COMPONENT ACPI_BUS_COMPONENT + ... + ACPI_DEBUG_PRINT((ACPI_DB_INFO, "Device insertion detected\n")); + +To turn on this message, set the ACPI_BUS_COMPONENT bit in acpi.debug_layer +and the ACPI_LV_INFO bit in acpi.debug_level. (The ACPI_DEBUG_PRINT +statement uses ACPI_DB_INFO, which is macro based on the ACPI_LV_INFO +definition.) + +Enable all AML "Debug" output (stores to the Debug object while interpreting +AML) during boot: + + acpi.debug_layer=0xffffffff acpi.debug_level=0x2 + +Enable PCI and PCI interrupt routing debug messages: + + acpi.debug_layer=0x400000 acpi.debug_level=0x4 + +Enable all ACPI hardware-related messages: + + acpi.debug_layer=0x2 acpi.debug_level=0xffffffff + +Enable all ACPI_DB_INFO messages after boot: + + # echo 0x4 > /sys/module/acpi/parameters/debug_level + +Show all valid component values: + + # cat /sys/module/acpi/parameters/debug_layer diff --git a/Documentation/acpi/dsd/data-node-references.txt b/Documentation/acpi/dsd/data-node-references.txt new file mode 100644 index 000000000..c3871565c --- /dev/null +++ b/Documentation/acpi/dsd/data-node-references.txt @@ -0,0 +1,89 @@ +Copyright (C) 2018 Intel Corporation +Author: Sakari Ailus <sakari.ailus@linux.intel.com> + + +Referencing hierarchical data nodes +----------------------------------- + +ACPI in general allows referring to device objects in the tree only. +Hierarchical data extension nodes may not be referred to directly, hence this +document defines a scheme to implement such references. + +A reference consist of the device object name followed by one or more +hierarchical data extension [1] keys. Specifically, the hierarchical data +extension node which is referred to by the key shall lie directly under the +parent object i.e. either the device object or another hierarchical data +extension node. + +The keys in the hierarchical data nodes shall consist of the name of the node, +"@" character and the number of the node in hexadecimal notation (without pre- +or postfixes). The same ACPI object shall include the _DSD property extension +with a property "reg" that shall have the same numerical value as the number of +the node. + +In case a hierarchical data extensions node has no numerical value, then the +"reg" property shall be omitted from the ACPI object's _DSD properties and the +"@" character and the number shall be omitted from the hierarchical data +extension key. + + +Example +------- + + In the ASL snippet below, the "reference" _DSD property [2] contains a + device object reference to DEV0 and under that device object, a + hierarchical data extension key "node@1" referring to the NOD1 object + and lastly, a hierarchical data extension key "anothernode" referring to + the ANOD object which is also the final target node of the reference. + + Device (DEV0) + { + Name (_DSD, Package () { + ToUUID("dbb8e3e6-5886-4ba6-8795-1319f52a966b"), + Package () { + Package () { "node@0", NOD0 }, + Package () { "node@1", NOD1 }, + } + }) + Name (NOD0, Package() { + ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"), + Package () { + Package () { "random-property", 3 }, + } + }) + Name (NOD1, Package() { + ToUUID("dbb8e3e6-5886-4ba6-8795-1319f52a966b"), + Package () { + Package () { "anothernode", ANOD }, + } + }) + Name (ANOD, Package() { + ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"), + Package () { + Package () { "random-property", 0 }, + } + }) + } + + Device (DEV1) + { + Name (_DSD, Package () { + ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"), + Package () { + Package () { "reference", ^DEV0, "node@1", "anothernode" }, + } + }) + } + +Please also see a graph example in graph.txt . + +References +---------- + +[1] Hierarchical Data Extension UUID For _DSD. + <URL:http://www.uefi.org/sites/default/files/resources/_DSD-hierarchical-data-extension-UUID-v1.1.pdf>, + referenced 2018-07-17. + +[2] Device Properties UUID For _DSD. + <URL:http://www.uefi.org/sites/default/files/resources/_DSD-device-properties-UUID.pdf>, + referenced 2016-10-04. diff --git a/Documentation/acpi/dsd/graph.txt b/Documentation/acpi/dsd/graph.txt new file mode 100644 index 000000000..b9ce91078 --- /dev/null +++ b/Documentation/acpi/dsd/graph.txt @@ -0,0 +1,174 @@ +Graphs + + +_DSD +---- + +_DSD (Device Specific Data) [7] is a predefined ACPI device +configuration object that can be used to convey information on +hardware features which are not specifically covered by the ACPI +specification [1][6]. There are two _DSD extensions that are relevant +for graphs: property [4] and hierarchical data extensions [5]. The +property extension provides generic key-value pairs whereas the +hierarchical data extension supports nodes with references to other +nodes, forming a tree. The nodes in the tree may contain properties as +defined by the property extension. The two extensions together provide +a tree-like structure with zero or more properties (key-value pairs) +in each node of the tree. + +The data structure may be accessed at runtime by using the device_* +and fwnode_* functions defined in include/linux/fwnode.h . + +Fwnode represents a generic firmware node object. It is independent on +the firmware type. In ACPI, fwnodes are _DSD hierarchical data +extensions objects. A device's _DSD object is represented by an +fwnode. + +The data structure may be referenced to elsewhere in the ACPI tables +by using a hard reference to the device itself and an index to the +hierarchical data extension array on each depth. + + +Ports and endpoints +------------------- + +The port and endpoint concepts are very similar to those in Devicetree +[3]. A port represents an interface in a device, and an endpoint +represents a connection to that interface. + +All port nodes are located under the device's "_DSD" node in the hierarchical +data extension tree. The data extension related to each port node must begin +with "port" and must be followed by the "@" character and the number of the port +as its key. The target object it refers to should be called "PRTX", where "X" is +the number of the port. An example of such a package would be: + + Package() { "port@4", PRT4 } + +Further on, endpoints are located under the port nodes. The hierarchical +data extension key of the endpoint nodes must begin with +"endpoint" and must be followed by the "@" character and the number of the +endpoint. The object it refers to should be called "EPXY", where "X" is the +number of the port and "Y" is the number of the endpoint. An example of such a +package would be: + + Package() { "endpoint@0", EP40 } + +Each port node contains a property extension key "port", the value of which is +the number of the port. Each endpoint is similarly numbered with a property +extension key "reg", the value of which is the number of the endpoint. Port +numbers must be unique within a device and endpoint numbers must be unique +within a port. If a device object may only has a single port, then the number +of that port shall be zero. Similarly, if a port may only have a single +endpoint, the number of that endpoint shall be zero. + +The endpoint reference uses property extension with "remote-endpoint" property +name followed by a reference in the same package. Such references consist of the +the remote device reference, the first package entry of the port data extension +reference under the device and finally the first package entry of the endpoint +data extension reference under the port. Individual references thus appear as: + + Package() { device, "port@X", "endpoint@Y" } + +In the above example, "X" is the number of the port and "Y" is the number of the +endpoint. + +The references to endpoints must be always done both ways, to the +remote endpoint and back from the referred remote endpoint node. + +A simple example of this is show below: + + Scope (\_SB.PCI0.I2C2) + { + Device (CAM0) + { + Name (_DSD, Package () { + ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"), + Package () { + Package () { "compatible", Package () { "nokia,smia" } }, + }, + ToUUID("dbb8e3e6-5886-4ba6-8795-1319f52a966b"), + Package () { + Package () { "port@0", PRT0 }, + } + }) + Name (PRT0, Package() { + ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"), + Package () { + Package () { "reg", 0 }, + }, + ToUUID("dbb8e3e6-5886-4ba6-8795-1319f52a966b"), + Package () { + Package () { "endpoint@0", EP00 }, + } + }) + Name (EP00, Package() { + ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"), + Package () { + Package () { "reg", 0 }, + Package () { "remote-endpoint", Package() { \_SB.PCI0.ISP, "port@4", "endpoint@0" } }, + } + }) + } + } + + Scope (\_SB.PCI0) + { + Device (ISP) + { + Name (_DSD, Package () { + ToUUID("dbb8e3e6-5886-4ba6-8795-1319f52a966b"), + Package () { + Package () { "port@4", PRT4 }, + } + }) + + Name (PRT4, Package() { + ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"), + Package () { + Package () { "reg", 4 }, /* CSI-2 port number */ + }, + ToUUID("dbb8e3e6-5886-4ba6-8795-1319f52a966b"), + Package () { + Package () { "endpoint@0", EP40 }, + } + }) + + Name (EP40, Package() { + ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"), + Package () { + Package () { "reg", 0 }, + Package () { "remote-endpoint", Package () { \_SB.PCI0.I2C2.CAM0, "port@0", "endpoint@0" } }, + } + }) + } + } + +Here, the port 0 of the "CAM0" device is connected to the port 4 of +the "ISP" device and vice versa. + + +References +---------- + +[1] _DSD (Device Specific Data) Implementation Guide. + <URL:http://www.uefi.org/sites/default/files/resources/_DSD-implementation-guide-toplevel-1_1.htm>, + referenced 2016-10-03. + +[2] Devicetree. <URL:http://www.devicetree.org>, referenced 2016-10-03. + +[3] Documentation/devicetree/bindings/graph.txt + +[4] Device Properties UUID For _DSD. + <URL:http://www.uefi.org/sites/default/files/resources/_DSD-device-properties-UUID.pdf>, + referenced 2016-10-04. + +[5] Hierarchical Data Extension UUID For _DSD. + <URL:http://www.uefi.org/sites/default/files/resources/_DSD-hierarchical-data-extension-UUID-v1.1.pdf>, + referenced 2016-10-04. + +[6] Advanced Configuration and Power Interface Specification. + <URL:http://www.uefi.org/sites/default/files/resources/ACPI_6_1.pdf>, + referenced 2016-10-04. + +[7] _DSD Device Properties Usage Rules. + Documentation/acpi/DSD-properties-rules.txt diff --git a/Documentation/acpi/dsdt-override.txt b/Documentation/acpi/dsdt-override.txt new file mode 100644 index 000000000..784841caa --- /dev/null +++ b/Documentation/acpi/dsdt-override.txt @@ -0,0 +1,7 @@ +Linux supports a method of overriding the BIOS DSDT: + +CONFIG_ACPI_CUSTOM_DSDT builds the image into the kernel. + +When to use this method is described in detail on the +Linux/ACPI home page: +https://01.org/linux-acpi/documentation/overriding-dsdt diff --git a/Documentation/acpi/enumeration.txt b/Documentation/acpi/enumeration.txt new file mode 100644 index 000000000..7bcf9c3d9 --- /dev/null +++ b/Documentation/acpi/enumeration.txt @@ -0,0 +1,426 @@ +ACPI based device enumeration +~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +ACPI 5 introduced a set of new resources (UartTSerialBus, I2cSerialBus, +SpiSerialBus, GpioIo and GpioInt) which can be used in enumerating slave +devices behind serial bus controllers. + +In addition we are starting to see peripherals integrated in the +SoC/Chipset to appear only in ACPI namespace. These are typically devices +that are accessed through memory-mapped registers. + +In order to support this and re-use the existing drivers as much as +possible we decided to do following: + + o Devices that have no bus connector resource are represented as + platform devices. + + o Devices behind real busses where there is a connector resource + are represented as struct spi_device or struct i2c_device + (standard UARTs are not busses so there is no struct uart_device). + +As both ACPI and Device Tree represent a tree of devices (and their +resources) this implementation follows the Device Tree way as much as +possible. + +The ACPI implementation enumerates devices behind busses (platform, SPI and +I2C), creates the physical devices and binds them to their ACPI handle in +the ACPI namespace. + +This means that when ACPI_HANDLE(dev) returns non-NULL the device was +enumerated from ACPI namespace. This handle can be used to extract other +device-specific configuration. There is an example of this below. + +Platform bus support +~~~~~~~~~~~~~~~~~~~~ +Since we are using platform devices to represent devices that are not +connected to any physical bus we only need to implement a platform driver +for the device and add supported ACPI IDs. If this same IP-block is used on +some other non-ACPI platform, the driver might work out of the box or needs +some minor changes. + +Adding ACPI support for an existing driver should be pretty +straightforward. Here is the simplest example: + + #ifdef CONFIG_ACPI + static const struct acpi_device_id mydrv_acpi_match[] = { + /* ACPI IDs here */ + { } + }; + MODULE_DEVICE_TABLE(acpi, mydrv_acpi_match); + #endif + + static struct platform_driver my_driver = { + ... + .driver = { + .acpi_match_table = ACPI_PTR(mydrv_acpi_match), + }, + }; + +If the driver needs to perform more complex initialization like getting and +configuring GPIOs it can get its ACPI handle and extract this information +from ACPI tables. + +DMA support +~~~~~~~~~~~ +DMA controllers enumerated via ACPI should be registered in the system to +provide generic access to their resources. For example, a driver that would +like to be accessible to slave devices via generic API call +dma_request_slave_channel() must register itself at the end of the probe +function like this: + + err = devm_acpi_dma_controller_register(dev, xlate_func, dw); + /* Handle the error if it's not a case of !CONFIG_ACPI */ + +and implement custom xlate function if needed (usually acpi_dma_simple_xlate() +is enough) which converts the FixedDMA resource provided by struct +acpi_dma_spec into the corresponding DMA channel. A piece of code for that case +could look like: + + #ifdef CONFIG_ACPI + struct filter_args { + /* Provide necessary information for the filter_func */ + ... + }; + + static bool filter_func(struct dma_chan *chan, void *param) + { + /* Choose the proper channel */ + ... + } + + static struct dma_chan *xlate_func(struct acpi_dma_spec *dma_spec, + struct acpi_dma *adma) + { + dma_cap_mask_t cap; + struct filter_args args; + + /* Prepare arguments for filter_func */ + ... + return dma_request_channel(cap, filter_func, &args); + } + #else + static struct dma_chan *xlate_func(struct acpi_dma_spec *dma_spec, + struct acpi_dma *adma) + { + return NULL; + } + #endif + +dma_request_slave_channel() will call xlate_func() for each registered DMA +controller. In the xlate function the proper channel must be chosen based on +information in struct acpi_dma_spec and the properties of the controller +provided by struct acpi_dma. + +Clients must call dma_request_slave_channel() with the string parameter that +corresponds to a specific FixedDMA resource. By default "tx" means the first +entry of the FixedDMA resource array, "rx" means the second entry. The table +below shows a layout: + + Device (I2C0) + { + ... + Method (_CRS, 0, NotSerialized) + { + Name (DBUF, ResourceTemplate () + { + FixedDMA (0x0018, 0x0004, Width32bit, _Y48) + FixedDMA (0x0019, 0x0005, Width32bit, ) + }) + ... + } + } + +So, the FixedDMA with request line 0x0018 is "tx" and next one is "rx" in +this example. + +In robust cases the client unfortunately needs to call +acpi_dma_request_slave_chan_by_index() directly and therefore choose the +specific FixedDMA resource by its index. + +SPI serial bus support +~~~~~~~~~~~~~~~~~~~~~~ +Slave devices behind SPI bus have SpiSerialBus resource attached to them. +This is extracted automatically by the SPI core and the slave devices are +enumerated once spi_register_master() is called by the bus driver. + +Here is what the ACPI namespace for a SPI slave might look like: + + Device (EEP0) + { + Name (_ADR, 1) + Name (_CID, Package() { + "ATML0025", + "AT25", + }) + ... + Method (_CRS, 0, NotSerialized) + { + SPISerialBus(1, PolarityLow, FourWireMode, 8, + ControllerInitiated, 1000000, ClockPolarityLow, + ClockPhaseFirst, "\\_SB.PCI0.SPI1",) + } + ... + +The SPI device drivers only need to add ACPI IDs in a similar way than with +the platform device drivers. Below is an example where we add ACPI support +to at25 SPI eeprom driver (this is meant for the above ACPI snippet): + + #ifdef CONFIG_ACPI + static const struct acpi_device_id at25_acpi_match[] = { + { "AT25", 0 }, + { }, + }; + MODULE_DEVICE_TABLE(acpi, at25_acpi_match); + #endif + + static struct spi_driver at25_driver = { + .driver = { + ... + .acpi_match_table = ACPI_PTR(at25_acpi_match), + }, + }; + +Note that this driver actually needs more information like page size of the +eeprom etc. but at the time writing this there is no standard way of +passing those. One idea is to return this in _DSM method like: + + Device (EEP0) + { + ... + Method (_DSM, 4, NotSerialized) + { + Store (Package (6) + { + "byte-len", 1024, + "addr-mode", 2, + "page-size, 32 + }, Local0) + + // Check UUIDs etc. + + Return (Local0) + } + +Then the at25 SPI driver can get this configuration by calling _DSM on its +ACPI handle like: + + struct acpi_buffer output = { ACPI_ALLOCATE_BUFFER, NULL }; + struct acpi_object_list input; + acpi_status status; + + /* Fill in the input buffer */ + + status = acpi_evaluate_object(ACPI_HANDLE(&spi->dev), "_DSM", + &input, &output); + if (ACPI_FAILURE(status)) + /* Handle the error */ + + /* Extract the data here */ + + kfree(output.pointer); + +I2C serial bus support +~~~~~~~~~~~~~~~~~~~~~~ +The slaves behind I2C bus controller only need to add the ACPI IDs like +with the platform and SPI drivers. The I2C core automatically enumerates +any slave devices behind the controller device once the adapter is +registered. + +Below is an example of how to add ACPI support to the existing mpu3050 +input driver: + + #ifdef CONFIG_ACPI + static const struct acpi_device_id mpu3050_acpi_match[] = { + { "MPU3050", 0 }, + { }, + }; + MODULE_DEVICE_TABLE(acpi, mpu3050_acpi_match); + #endif + + static struct i2c_driver mpu3050_i2c_driver = { + .driver = { + .name = "mpu3050", + .owner = THIS_MODULE, + .pm = &mpu3050_pm, + .of_match_table = mpu3050_of_match, + .acpi_match_table = ACPI_PTR(mpu3050_acpi_match), + }, + .probe = mpu3050_probe, + .remove = mpu3050_remove, + .id_table = mpu3050_ids, + }; + +GPIO support +~~~~~~~~~~~~ +ACPI 5 introduced two new resources to describe GPIO connections: GpioIo +and GpioInt. These resources can be used to pass GPIO numbers used by +the device to the driver. ACPI 5.1 extended this with _DSD (Device +Specific Data) which made it possible to name the GPIOs among other things. + +For example: + +Device (DEV) +{ + Method (_CRS, 0, NotSerialized) + { + Name (SBUF, ResourceTemplate() + { + ... + // Used to power on/off the device + GpioIo (Exclusive, PullDefault, 0x0000, 0x0000, + IoRestrictionOutputOnly, "\\_SB.PCI0.GPI0", + 0x00, ResourceConsumer,,) + { + // Pin List + 0x0055 + } + + // Interrupt for the device + GpioInt (Edge, ActiveHigh, ExclusiveAndWake, PullNone, + 0x0000, "\\_SB.PCI0.GPI0", 0x00, ResourceConsumer,,) + { + // Pin list + 0x0058 + } + + ... + + } + + Return (SBUF) + } + + // ACPI 5.1 _DSD used for naming the GPIOs + Name (_DSD, Package () + { + ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"), + Package () + { + Package () {"power-gpios", Package() {^DEV, 0, 0, 0 }}, + Package () {"irq-gpios", Package() {^DEV, 1, 0, 0 }}, + } + }) + ... + +These GPIO numbers are controller relative and path "\\_SB.PCI0.GPI0" +specifies the path to the controller. In order to use these GPIOs in Linux +we need to translate them to the corresponding Linux GPIO descriptors. + +There is a standard GPIO API for that and is documented in +Documentation/gpio/. + +In the above example we can get the corresponding two GPIO descriptors with +a code like this: + + #include <linux/gpio/consumer.h> + ... + + struct gpio_desc *irq_desc, *power_desc; + + irq_desc = gpiod_get(dev, "irq"); + if (IS_ERR(irq_desc)) + /* handle error */ + + power_desc = gpiod_get(dev, "power"); + if (IS_ERR(power_desc)) + /* handle error */ + + /* Now we can use the GPIO descriptors */ + +There are also devm_* versions of these functions which release the +descriptors once the device is released. + +See Documentation/acpi/gpio-properties.txt for more information about the +_DSD binding related to GPIOs. + +MFD devices +~~~~~~~~~~~ +The MFD devices register their children as platform devices. For the child +devices there needs to be an ACPI handle that they can use to reference +parts of the ACPI namespace that relate to them. In the Linux MFD subsystem +we provide two ways: + + o The children share the parent ACPI handle. + o The MFD cell can specify the ACPI id of the device. + +For the first case, the MFD drivers do not need to do anything. The +resulting child platform device will have its ACPI_COMPANION() set to point +to the parent device. + +If the ACPI namespace has a device that we can match using an ACPI id or ACPI +adr, the cell should be set like: + + static struct mfd_cell_acpi_match my_subdevice_cell_acpi_match = { + .pnpid = "XYZ0001", + .adr = 0, + }; + + static struct mfd_cell my_subdevice_cell = { + .name = "my_subdevice", + /* set the resources relative to the parent */ + .acpi_match = &my_subdevice_cell_acpi_match, + }; + +The ACPI id "XYZ0001" is then used to lookup an ACPI device directly under +the MFD device and if found, that ACPI companion device is bound to the +resulting child platform device. + +Device Tree namespace link device ID +~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +The Device Tree protocol uses device identification based on the "compatible" +property whose value is a string or an array of strings recognized as device +identifiers by drivers and the driver core. The set of all those strings may be +regarded as a device identification namespace analogous to the ACPI/PNP device +ID namespace. Consequently, in principle it should not be necessary to allocate +a new (and arguably redundant) ACPI/PNP device ID for a devices with an existing +identification string in the Device Tree (DT) namespace, especially if that ID +is only needed to indicate that a given device is compatible with another one, +presumably having a matching driver in the kernel already. + +In ACPI, the device identification object called _CID (Compatible ID) is used to +list the IDs of devices the given one is compatible with, but those IDs must +belong to one of the namespaces prescribed by the ACPI specification (see +Section 6.1.2 of ACPI 6.0 for details) and the DT namespace is not one of them. +Moreover, the specification mandates that either a _HID or an _ADR identification +object be present for all ACPI objects representing devices (Section 6.1 of ACPI +6.0). For non-enumerable bus types that object must be _HID and its value must +be a device ID from one of the namespaces prescribed by the specification too. + +The special DT namespace link device ID, PRP0001, provides a means to use the +existing DT-compatible device identification in ACPI and to satisfy the above +requirements following from the ACPI specification at the same time. Namely, +if PRP0001 is returned by _HID, the ACPI subsystem will look for the +"compatible" property in the device object's _DSD and will use the value of that +property to identify the corresponding device in analogy with the original DT +device identification algorithm. If the "compatible" property is not present +or its value is not valid, the device will not be enumerated by the ACPI +subsystem. Otherwise, it will be enumerated automatically as a platform device +(except when an I2C or SPI link from the device to its parent is present, in +which case the ACPI core will leave the device enumeration to the parent's +driver) and the identification strings from the "compatible" property value will +be used to find a driver for the device along with the device IDs listed by _CID +(if present). + +Analogously, if PRP0001 is present in the list of device IDs returned by _CID, +the identification strings listed by the "compatible" property value (if present +and valid) will be used to look for a driver matching the device, but in that +case their relative priority with respect to the other device IDs listed by +_HID and _CID depends on the position of PRP0001 in the _CID return package. +Specifically, the device IDs returned by _HID and preceding PRP0001 in the _CID +return package will be checked first. Also in that case the bus type the device +will be enumerated to depends on the device ID returned by _HID. + +It is valid to define device objects with a _HID returning PRP0001 and without +the "compatible" property in the _DSD or a _CID as long as one of their +ancestors provides a _DSD with a valid "compatible" property. Such device +objects are then simply regarded as additional "blocks" providing hierarchical +configuration information to the driver of the composite ancestor device. + +However, PRP0001 can only be returned from either _HID or _CID of a device +object if all of the properties returned by the _DSD associated with it (either +the _DSD of the device object itself or the _DSD of its ancestor in the +"composite device" case described above) can be used in the ACPI environment. +Otherwise, the _DSD itself is regarded as invalid and therefore the "compatible" +property returned by it is meaningless. + +Refer to DSD-properties-rules.txt for more information. diff --git a/Documentation/acpi/gpio-properties.txt b/Documentation/acpi/gpio-properties.txt new file mode 100644 index 000000000..88c65cb5b --- /dev/null +++ b/Documentation/acpi/gpio-properties.txt @@ -0,0 +1,223 @@ +_DSD Device Properties Related to GPIO +-------------------------------------- + +With the release of ACPI 5.1, the _DSD configuration object finally +allows names to be given to GPIOs (and other things as well) returned +by _CRS. Previously, we were only able to use an integer index to find +the corresponding GPIO, which is pretty error prone (it depends on +the _CRS output ordering, for example). + +With _DSD we can now query GPIOs using a name instead of an integer +index, like the ASL example below shows: + + // Bluetooth device with reset and shutdown GPIOs + Device (BTH) + { + Name (_HID, ...) + + Name (_CRS, ResourceTemplate () + { + GpioIo (Exclusive, PullUp, 0, 0, IoRestrictionInputOnly, + "\\_SB.GPO0", 0, ResourceConsumer) {15} + GpioIo (Exclusive, PullUp, 0, 0, IoRestrictionInputOnly, + "\\_SB.GPO0", 0, ResourceConsumer) {27, 31} + }) + + Name (_DSD, Package () + { + ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"), + Package () + { + Package () {"reset-gpios", Package() {^BTH, 1, 1, 0 }}, + Package () {"shutdown-gpios", Package() {^BTH, 0, 0, 0 }}, + } + }) + } + +The format of the supported GPIO property is: + + Package () { "name", Package () { ref, index, pin, active_low }} + + ref - The device that has _CRS containing GpioIo()/GpioInt() resources, + typically this is the device itself (BTH in our case). + index - Index of the GpioIo()/GpioInt() resource in _CRS starting from zero. + pin - Pin in the GpioIo()/GpioInt() resource. Typically this is zero. + active_low - If 1 the GPIO is marked as active_low. + +Since ACPI GpioIo() resource does not have a field saying whether it is +active low or high, the "active_low" argument can be used here. Setting +it to 1 marks the GPIO as active low. + +In our Bluetooth example the "reset-gpios" refers to the second GpioIo() +resource, second pin in that resource with the GPIO number of 31. + +It is possible to leave holes in the array of GPIOs. This is useful in +cases like with SPI host controllers where some chip selects may be +implemented as GPIOs and some as native signals. For example a SPI host +controller can have chip selects 0 and 2 implemented as GPIOs and 1 as +native: + + Package () { + "cs-gpios", + Package () { + ^GPIO, 19, 0, 0, // chip select 0: GPIO + 0, // chip select 1: native signal + ^GPIO, 20, 0, 0, // chip select 2: GPIO + } + } + +Other supported properties +-------------------------- + +Following Device Tree compatible device properties are also supported by +_DSD device properties for GPIO controllers: + +- gpio-hog +- output-high +- output-low +- input +- line-name + +Example: + + Name (_DSD, Package () { + // _DSD Hierarchical Properties Extension UUID + ToUUID("dbb8e3e6-5886-4ba6-8795-1319f52a966b"), + Package () { + Package () {"hog-gpio8", "G8PU"} + } + }) + + Name (G8PU, Package () { + ToUUID("daffd814-6eba-4d8c-8a91-bc9bbf4aa301"), + Package () { + Package () {"gpio-hog", 1}, + Package () {"gpios", Package () {8, 0}}, + Package () {"output-high", 1}, + Package () {"line-name", "gpio8-pullup"}, + } + }) + +- gpio-line-names + +Example: + + Package () { + "gpio-line-names", + Package () { + "SPI0_CS_N", "EXP2_INT", "MUX6_IO", "UART0_RXD", "MUX7_IO", + "LVL_C_A1", "MUX0_IO", "SPI1_MISO" + } + } + +See Documentation/devicetree/bindings/gpio/gpio.txt for more information +about these properties. + +ACPI GPIO Mappings Provided by Drivers +-------------------------------------- + +There are systems in which the ACPI tables do not contain _DSD but provide _CRS +with GpioIo()/GpioInt() resources and device drivers still need to work with +them. + +In those cases ACPI device identification objects, _HID, _CID, _CLS, _SUB, _HRV, +available to the driver can be used to identify the device and that is supposed +to be sufficient to determine the meaning and purpose of all of the GPIO lines +listed by the GpioIo()/GpioInt() resources returned by _CRS. In other words, +the driver is supposed to know what to use the GpioIo()/GpioInt() resources for +once it has identified the device. Having done that, it can simply assign names +to the GPIO lines it is going to use and provide the GPIO subsystem with a +mapping between those names and the ACPI GPIO resources corresponding to them. + +To do that, the driver needs to define a mapping table as a NULL-terminated +array of struct acpi_gpio_mapping objects that each contain a name, a pointer +to an array of line data (struct acpi_gpio_params) objects and the size of that +array. Each struct acpi_gpio_params object consists of three fields, +crs_entry_index, line_index, active_low, representing the index of the target +GpioIo()/GpioInt() resource in _CRS starting from zero, the index of the target +line in that resource starting from zero, and the active-low flag for that line, +respectively, in analogy with the _DSD GPIO property format specified above. + +For the example Bluetooth device discussed previously the data structures in +question would look like this: + +static const struct acpi_gpio_params reset_gpio = { 1, 1, false }; +static const struct acpi_gpio_params shutdown_gpio = { 0, 0, false }; + +static const struct acpi_gpio_mapping bluetooth_acpi_gpios[] = { + { "reset-gpios", &reset_gpio, 1 }, + { "shutdown-gpios", &shutdown_gpio, 1 }, + { }, +}; + +Next, the mapping table needs to be passed as the second argument to +acpi_dev_add_driver_gpios() that will register it with the ACPI device object +pointed to by its first argument. That should be done in the driver's .probe() +routine. On removal, the driver should unregister its GPIO mapping table by +calling acpi_dev_remove_driver_gpios() on the ACPI device object where that +table was previously registered. + +Using the _CRS fallback +----------------------- + +If a device does not have _DSD or the driver does not create ACPI GPIO +mapping, the Linux GPIO framework refuses to return any GPIOs. This is +because the driver does not know what it actually gets. For example if we +have a device like below: + + Device (BTH) + { + Name (_HID, ...) + + Name (_CRS, ResourceTemplate () { + GpioIo (Exclusive, PullNone, 0, 0, IoRestrictionNone, + "\\_SB.GPO0", 0, ResourceConsumer) {15} + GpioIo (Exclusive, PullNone, 0, 0, IoRestrictionNone, + "\\_SB.GPO0", 0, ResourceConsumer) {27} + }) + } + +The driver might expect to get the right GPIO when it does: + + desc = gpiod_get(dev, "reset", GPIOD_OUT_LOW); + +but since there is no way to know the mapping between "reset" and +the GpioIo() in _CRS desc will hold ERR_PTR(-ENOENT). + +The driver author can solve this by passing the mapping explictly +(the recommended way and documented in the above chapter). + +The ACPI GPIO mapping tables should not contaminate drivers that are not +knowing about which exact device they are servicing on. It implies that +the ACPI GPIO mapping tables are hardly linked to ACPI ID and certain +objects, as listed in the above chapter, of the device in question. + +Getting GPIO descriptor +----------------------- + +There are two main approaches to get GPIO resource from ACPI: + desc = gpiod_get(dev, connection_id, flags); + desc = gpiod_get_index(dev, connection_id, index, flags); + +We may consider two different cases here, i.e. when connection ID is +provided and otherwise. + +Case 1: + desc = gpiod_get(dev, "non-null-connection-id", flags); + desc = gpiod_get_index(dev, "non-null-connection-id", index, flags); + +Case 2: + desc = gpiod_get(dev, NULL, flags); + desc = gpiod_get_index(dev, NULL, index, flags); + +Case 1 assumes that corresponding ACPI device description must have +defined device properties and will prevent to getting any GPIO resources +otherwise. + +Case 2 explicitly tells GPIO core to look for resources in _CRS. + +Be aware that gpiod_get_index() in cases 1 and 2, assuming that there +are two versions of ACPI device description provided and no mapping is +present in the driver, will return different resources. That's why a +certain driver has to handle them carefully as explained in previous +chapter. diff --git a/Documentation/acpi/i2c-muxes.txt b/Documentation/acpi/i2c-muxes.txt new file mode 100644 index 000000000..9fcc4f0b8 --- /dev/null +++ b/Documentation/acpi/i2c-muxes.txt @@ -0,0 +1,58 @@ +ACPI I2C Muxes +-------------- + +Describing an I2C device hierarchy that includes I2C muxes requires an ACPI +Device () scope per mux channel. + +Consider this topology: + ++------+ +------+ +| SMB1 |-->| MUX0 |--CH00--> i2c client A (0x50) +| | | 0x70 |--CH01--> i2c client B (0x50) ++------+ +------+ + +which corresponds to the following ASL: + +Device (SMB1) +{ + Name (_HID, ...) + Device (MUX0) + { + Name (_HID, ...) + Name (_CRS, ResourceTemplate () { + I2cSerialBus (0x70, ControllerInitiated, I2C_SPEED, + AddressingMode7Bit, "^SMB1", 0x00, + ResourceConsumer,,) + } + + Device (CH00) + { + Name (_ADR, 0) + + Device (CLIA) + { + Name (_HID, ...) + Name (_CRS, ResourceTemplate () { + I2cSerialBus (0x50, ControllerInitiated, I2C_SPEED, + AddressingMode7Bit, "^CH00", 0x00, + ResourceConsumer,,) + } + } + } + + Device (CH01) + { + Name (_ADR, 1) + + Device (CLIB) + { + Name (_HID, ...) + Name (_CRS, ResourceTemplate () { + I2cSerialBus (0x50, ControllerInitiated, I2C_SPEED, + AddressingMode7Bit, "^CH01", 0x00, + ResourceConsumer,,) + } + } + } + } +} diff --git a/Documentation/acpi/initrd_table_override.txt b/Documentation/acpi/initrd_table_override.txt new file mode 100644 index 000000000..eb651a6aa --- /dev/null +++ b/Documentation/acpi/initrd_table_override.txt @@ -0,0 +1,107 @@ +Upgrading ACPI tables via initrd +================================ + +1) Introduction (What is this about) +2) What is this for +3) How does it work +4) References (Where to retrieve userspace tools) + +1) What is this about +--------------------- + +If the ACPI_TABLE_UPGRADE compile option is true, it is possible to +upgrade the ACPI execution environment that is defined by the ACPI tables +via upgrading the ACPI tables provided by the BIOS with an instrumented, +modified, more recent version one, or installing brand new ACPI tables. + +For a full list of ACPI tables that can be upgraded/installed, take a look +at the char *table_sigs[MAX_ACPI_SIGNATURE]; definition in +drivers/acpi/tables.c. +All ACPI tables iasl (Intel's ACPI compiler and disassembler) knows should +be overridable, except: + - ACPI_SIG_RSDP (has a signature of 6 bytes) + - ACPI_SIG_FACS (does not have an ordinary ACPI table header) +Both could get implemented as well. + + +2) What is this for +------------------- + +Complain to your platform/BIOS vendor if you find a bug which is so severe +that a workaround is not accepted in the Linux kernel. And this facility +allows you to upgrade the buggy tables before your platform/BIOS vendor +releases an upgraded BIOS binary. + +This facility can be used by platform/BIOS vendors to provide a Linux +compatible environment without modifying the underlying platform firmware. + +This facility also provides a powerful feature to easily debug and test +ACPI BIOS table compatibility with the Linux kernel by modifying old +platform provided ACPI tables or inserting new ACPI tables. + +It can and should be enabled in any kernel because there is no functional +change with not instrumented initrds. + + +3) How does it work +------------------- + +# Extract the machine's ACPI tables: +cd /tmp +acpidump >acpidump +acpixtract -a acpidump +# Disassemble, modify and recompile them: +iasl -d *.dat +# For example add this statement into a _PRT (PCI Routing Table) function +# of the DSDT: +Store("HELLO WORLD", debug) +# And increase the OEM Revision. For example, before modification: +DefinitionBlock ("DSDT.aml", "DSDT", 2, "INTEL ", "TEMPLATE", 0x00000000) +# After modification: +DefinitionBlock ("DSDT.aml", "DSDT", 2, "INTEL ", "TEMPLATE", 0x00000001) +iasl -sa dsdt.dsl +# Add the raw ACPI tables to an uncompressed cpio archive. +# They must be put into a /kernel/firmware/acpi directory inside the cpio +# archive. Note that if the table put here matches a platform table +# (similar Table Signature, and similar OEMID, and similar OEM Table ID) +# with a more recent OEM Revision, the platform table will be upgraded by +# this table. If the table put here doesn't match a platform table +# (dissimilar Table Signature, or dissimilar OEMID, or dissimilar OEM Table +# ID), this table will be appended. +mkdir -p kernel/firmware/acpi +cp dsdt.aml kernel/firmware/acpi +# A maximum of "NR_ACPI_INITRD_TABLES (64)" tables are currently allowed +# (see osl.c): +iasl -sa facp.dsl +iasl -sa ssdt1.dsl +cp facp.aml kernel/firmware/acpi +cp ssdt1.aml kernel/firmware/acpi +# The uncompressed cpio archive must be the first. Other, typically +# compressed cpio archives, must be concatenated on top of the uncompressed +# one. Following command creates the uncompressed cpio archive and +# concatenates the original initrd on top: +find kernel | cpio -H newc --create > /boot/instrumented_initrd +cat /boot/initrd >>/boot/instrumented_initrd +# reboot with increased acpi debug level, e.g. boot params: +acpi.debug_level=0x2 acpi.debug_layer=0xFFFFFFFF +# and check your syslog: +[ 1.268089] ACPI: PCI Interrupt Routing Table [\_SB_.PCI0._PRT] +[ 1.272091] [ACPI Debug] String [0x0B] "HELLO WORLD" + +iasl is able to disassemble and recompile quite a lot different, +also static ACPI tables. + + +4) Where to retrieve userspace tools +------------------------------------ + +iasl and acpixtract are part of Intel's ACPICA project: +http://acpica.org/ +and should be packaged by distributions (for example in the acpica package +on SUSE). + +acpidump can be found in Len Browns pmtools: +ftp://kernel.org/pub/linux/kernel/people/lenb/acpi/utils/pmtools/acpidump +This tool is also part of the acpica package on SUSE. +Alternatively, used ACPI tables can be retrieved via sysfs in latest kernels: +/sys/firmware/acpi/tables diff --git a/Documentation/acpi/linuxized-acpica.txt b/Documentation/acpi/linuxized-acpica.txt new file mode 100644 index 000000000..3ad7b0dfb --- /dev/null +++ b/Documentation/acpi/linuxized-acpica.txt @@ -0,0 +1,262 @@ +Linuxized ACPICA - Introduction to ACPICA Release Automation + +Copyright (C) 2013-2016, Intel Corporation +Author: Lv Zheng <lv.zheng@intel.com> + + +Abstract: + +This document describes the ACPICA project and the relationship between +ACPICA and Linux. It also describes how ACPICA code in drivers/acpi/acpica, +include/acpi and tools/power/acpi is automatically updated to follow the +upstream. + + +1. ACPICA Project + + The ACPI Component Architecture (ACPICA) project provides an operating + system (OS)-independent reference implementation of the Advanced + Configuration and Power Interface Specification (ACPI). It has been + adapted by various host OSes. By directly integrating ACPICA, Linux can + also benefit from the application experiences of ACPICA from other host + OSes. + + The homepage of ACPICA project is: www.acpica.org, it is maintained and + supported by Intel Corporation. + + The following figure depicts the Linux ACPI subsystem where the ACPICA + adaptation is included: + + +---------------------------------------------------------+ + | | + | +---------------------------------------------------+ | + | | +------------------+ | | + | | | Table Management | | | + | | +------------------+ | | + | | +----------------------+ | | + | | | Namespace Management | | | + | | +----------------------+ | | + | | +------------------+ ACPICA Components | | + | | | Event Management | | | + | | +------------------+ | | + | | +---------------------+ | | + | | | Resource Management | | | + | | +---------------------+ | | + | | +---------------------+ | | + | | | Hardware Management | | | + | | +---------------------+ | | + | +---------------------------------------------------+ | | + | | | +------------------+ | | | + | | | | OS Service Layer | | | | + | | | +------------------+ | | | + | | +-------------------------------------------------|-+ | + | | +--------------------+ | | + | | | Device Enumeration | | | + | | +--------------------+ | | + | | +------------------+ | | + | | | Power Management | | | + | | +------------------+ Linux/ACPI Components | | + | | +--------------------+ | | + | | | Thermal Management | | | + | | +--------------------+ | | + | | +--------------------------+ | | + | | | Drivers for ACPI Devices | | | + | | +--------------------------+ | | + | | +--------+ | | + | | | ...... | | | + | | +--------+ | | + | +---------------------------------------------------+ | + | | + +---------------------------------------------------------+ + + Figure 1. Linux ACPI Software Components + + NOTE: + A. OS Service Layer - Provided by Linux to offer OS dependent + implementation of the predefined ACPICA interfaces (acpi_os_*). + include/acpi/acpiosxf.h + drivers/acpi/osl.c + include/acpi/platform + include/asm/acenv.h + B. ACPICA Functionality - Released from ACPICA code base to offer + OS independent implementation of the ACPICA interfaces (acpi_*). + drivers/acpi/acpica + include/acpi/ac*.h + tools/power/acpi + C. Linux/ACPI Functionality - Providing Linux specific ACPI + functionality to the other Linux kernel subsystems and user space + programs. + drivers/acpi + include/linux/acpi.h + include/linux/acpi*.h + include/acpi + tools/power/acpi + D. Architecture Specific ACPICA/ACPI Functionalities - Provided by the + ACPI subsystem to offer architecture specific implementation of the + ACPI interfaces. They are Linux specific components and are out of + the scope of this document. + include/asm/acpi.h + include/asm/acpi*.h + arch/*/acpi + +2. ACPICA Release + + The ACPICA project maintains its code base at the following repository URL: + https://github.com/acpica/acpica.git. As a rule, a release is made every + month. + + As the coding style adopted by the ACPICA project is not acceptable by + Linux, there is a release process to convert the ACPICA git commits into + Linux patches. The patches generated by this process are referred to as + "linuxized ACPICA patches". The release process is carried out on a local + copy the ACPICA git repository. Each commit in the monthly release is + converted into a linuxized ACPICA patch. Together, they form the monthly + ACPICA release patchset for the Linux ACPI community. This process is + illustrated in the following figure: + + +-----------------------------+ + | acpica / master (-) commits | + +-----------------------------+ + /|\ | + | \|/ + | /---------------------\ +----------------------+ + | < Linuxize repo Utility >-->| old linuxized acpica |--+ + | \---------------------/ +----------------------+ | + | | + /---------\ | + < git reset > \ + \---------/ \ + /|\ /+-+ + | / | + +-----------------------------+ | | + | acpica / master (+) commits | | | + +-----------------------------+ | | + | | | + \|/ | | + /-----------------------\ +----------------------+ | | + < Linuxize repo Utilities >-->| new linuxized acpica |--+ | + \-----------------------/ +----------------------+ | + \|/ + +--------------------------+ /----------------------\ + | Linuxized ACPICA Patches |<----------------< Linuxize patch Utility > + +--------------------------+ \----------------------/ + | + \|/ + /---------------------------\ + < Linux ACPI Community Review > + \---------------------------/ + | + \|/ + +-----------------------+ /------------------\ +----------------+ + | linux-pm / linux-next |-->< Linux Merge Window >-->| linux / master | + +-----------------------+ \------------------/ +----------------+ + + Figure 2. ACPICA -> Linux Upstream Process + + NOTE: + A. Linuxize Utilities - Provided by the ACPICA repository, including a + utility located in source/tools/acpisrc folder and a number of + scripts located in generate/linux folder. + B. acpica / master - "master" branch of the git repository at + <https://github.com/acpica/acpica.git>. + C. linux-pm / linux-next - "linux-next" branch of the git repository at + <http://git.kernel.org/pub/scm/linux/kernel/git/rafael/linux-pm.git>. + D. linux / master - "master" branch of the git repository at + <http://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git>. + + Before the linuxized ACPICA patches are sent to the Linux ACPI community + for review, there is a quality assurance build test process to reduce + porting issues. Currently this build process only takes care of the + following kernel configuration options: + CONFIG_ACPI/CONFIG_ACPI_DEBUG/CONFIG_ACPI_DEBUGGER + +3. ACPICA Divergences + + Ideally, all of the ACPICA commits should be converted into Linux patches + automatically without manual modifications, the "linux / master" tree should + contain the ACPICA code that exactly corresponds to the ACPICA code + contained in "new linuxized acpica" tree and it should be possible to run + the release process fully automatically. + + As a matter of fact, however, there are source code differences between + the ACPICA code in Linux and the upstream ACPICA code, referred to as + "ACPICA Divergences". + + The various sources of ACPICA divergences include: + 1. Legacy divergences - Before the current ACPICA release process was + established, there already had been divergences between Linux and + ACPICA. Over the past several years those divergences have been greatly + reduced, but there still are several ones and it takes time to figure + out the underlying reasons for their existence. + 2. Manual modifications - Any manual modification (eg. coding style fixes) + made directly in the Linux sources obviously hurts the ACPICA release + automation. Thus it is recommended to fix such issues in the ACPICA + upstream source code and generate the linuxized fix using the ACPICA + release utilities (please refer to Section 4 below for the details). + 3. Linux specific features - Sometimes it's impossible to use the + current ACPICA APIs to implement features required by the Linux kernel, + so Linux developers occasionally have to change ACPICA code directly. + Those changes may not be acceptable by ACPICA upstream and in such cases + they are left as committed ACPICA divergences unless the ACPICA side can + implement new mechanisms as replacements for them. + 4. ACPICA release fixups - ACPICA only tests commits using a set of the + user space simulation utilities, thus the linuxized ACPICA patches may + break the Linux kernel, leaving us build/boot failures. In order to + avoid breaking Linux bisection, fixes are applied directly to the + linuxized ACPICA patches during the release process. When the release + fixups are backported to the upstream ACPICA sources, they must follow + the upstream ACPICA rules and so further modifications may appear. + That may result in the appearance of new divergences. + 5. Fast tracking of ACPICA commits - Some ACPICA commits are regression + fixes or stable-candidate material, so they are applied in advance with + respect to the ACPICA release process. If such commits are reverted or + rebased on the ACPICA side in order to offer better solutions, new ACPICA + divergences are generated. + +4. ACPICA Development + + This paragraph guides Linux developers to use the ACPICA upstream release + utilities to obtain Linux patches corresponding to upstream ACPICA commits + before they become available from the ACPICA release process. + + 1. Cherry-pick an ACPICA commit + + First you need to git clone the ACPICA repository and the ACPICA change + you want to cherry pick must be committed into the local repository. + + Then the gen-patch.sh command can help to cherry-pick an ACPICA commit + from the ACPICA local repository: + + $ git clone https://github.com/acpica/acpica + $ cd acpica + $ generate/linux/gen-patch.sh -u [commit ID] + + Here the commit ID is the ACPICA local repository commit ID you want to + cherry pick. It can be omitted if the commit is "HEAD". + + 2. Cherry-pick recent ACPICA commits + + Sometimes you need to rebase your code on top of the most recent ACPICA + changes that haven't been applied to Linux yet. + + You can generate the ACPICA release series yourself and rebase your code on + top of the generated ACPICA release patches: + + $ git clone https://github.com/acpica/acpica + $ cd acpica + $ generate/linux/make-patches.sh -u [commit ID] + + The commit ID should be the last ACPICA commit accepted by Linux. Usually, + it is the commit modifying ACPI_CA_VERSION. It can be found by executing + "git blame source/include/acpixf.h" and referencing the line that contains + "ACPI_CA_VERSION". + + 3. Inspect the current divergences + + If you have local copies of both Linux and upstream ACPICA, you can generate + a diff file indicating the state of the current divergences: + + # git clone https://github.com/acpica/acpica + # git clone http://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git + # cd acpica + # generate/linux/divergences.sh -s ../linux diff --git a/Documentation/acpi/lpit.txt b/Documentation/acpi/lpit.txt new file mode 100644 index 000000000..b426398d2 --- /dev/null +++ b/Documentation/acpi/lpit.txt @@ -0,0 +1,25 @@ +To enumerate platform Low Power Idle states, Intel platforms are using +“Low Power Idle Table” (LPIT). More details about this table can be +downloaded from: +http://www.uefi.org/sites/default/files/resources/Intel_ACPI_Low_Power_S0_Idle.pdf + +Residencies for each low power state can be read via FFH +(Function fixed hardware) or a memory mapped interface. + +On platforms supporting S0ix sleep states, there can be two types of +residencies: +- CPU PKG C10 (Read via FFH interface) +- Platform Controller Hub (PCH) SLP_S0 (Read via memory mapped interface) + +The following attributes are added dynamically to the cpuidle +sysfs attribute group: + /sys/devices/system/cpu/cpuidle/low_power_idle_cpu_residency_us + /sys/devices/system/cpu/cpuidle/low_power_idle_system_residency_us + +The "low_power_idle_cpu_residency_us" attribute shows time spent +by the CPU package in PKG C10 + +The "low_power_idle_system_residency_us" attribute shows SLP_S0 +residency, or system time spent with the SLP_S0# signal asserted. +This is the lowest possible system power state, achieved only when CPU is in +PKG C10 and all functional blocks in PCH are in a low power state. diff --git a/Documentation/acpi/method-customizing.txt b/Documentation/acpi/method-customizing.txt new file mode 100644 index 000000000..7235da975 --- /dev/null +++ b/Documentation/acpi/method-customizing.txt @@ -0,0 +1,73 @@ +Linux ACPI Custom Control Method How To +======================================= + +Written by Zhang Rui <rui.zhang@intel.com> + + +Linux supports customizing ACPI control methods at runtime. + +Users can use this to +1. override an existing method which may not work correctly, + or just for debugging purposes. +2. insert a completely new method in order to create a missing + method such as _OFF, _ON, _STA, _INI, etc. +For these cases, it is far simpler to dynamically install a single +control method rather than override the entire DSDT, because kernel +rebuild/reboot is not needed and test result can be got in minutes. + +Note: Only ACPI METHOD can be overridden, any other object types like + "Device", "OperationRegion", are not recognized. Methods + declared inside scope operators are also not supported. +Note: The same ACPI control method can be overridden for many times, + and it's always the latest one that used by Linux/kernel. +Note: To get the ACPI debug object output (Store (AAAA, Debug)), + please run "echo 1 > /sys/module/acpi/parameters/aml_debug_output". + +1. override an existing method + a) get the ACPI table via ACPI sysfs I/F. e.g. to get the DSDT, + just run "cat /sys/firmware/acpi/tables/DSDT > /tmp/dsdt.dat" + b) disassemble the table by running "iasl -d dsdt.dat". + c) rewrite the ASL code of the method and save it in a new file, + d) package the new file (psr.asl) to an ACPI table format. + Here is an example of a customized \_SB._AC._PSR method, + + DefinitionBlock ("", "SSDT", 1, "", "", 0x20080715) + { + Method (\_SB_.AC._PSR, 0, NotSerialized) + { + Store ("In AC _PSR", Debug) + Return (ACON) + } + } + Note that the full pathname of the method in ACPI namespace + should be used. + e) assemble the file to generate the AML code of the method. + e.g. "iasl -vw 6084 psr.asl" (psr.aml is generated as a result) + If parameter "-vw 6084" is not supported by your iASL compiler, + please try a newer version. + f) mount debugfs by "mount -t debugfs none /sys/kernel/debug" + g) override the old method via the debugfs by running + "cat /tmp/psr.aml > /sys/kernel/debug/acpi/custom_method" + +2. insert a new method + This is easier than overriding an existing method. + We just need to create the ASL code of the method we want to + insert and then follow the step c) ~ g) in section 1. + +3. undo your changes + The "undo" operation is not supported for a new inserted method + right now, i.e. we can not remove a method currently. + For an overridden method, in order to undo your changes, please + save a copy of the method original ASL code in step c) section 1, + and redo step c) ~ g) to override the method with the original one. + + +Note: We can use a kernel with multiple custom ACPI method running, + But each individual write to debugfs can implement a SINGLE + method override. i.e. if we want to insert/override multiple + ACPI methods, we need to redo step c) ~ g) for multiple times. + +Note: Be aware that root can mis-use this driver to modify arbitrary + memory and gain additional rights, if root's privileges got + restricted (for example if root is not allowed to load additional + modules after boot). diff --git a/Documentation/acpi/method-tracing.txt b/Documentation/acpi/method-tracing.txt new file mode 100644 index 000000000..0aba14c8f --- /dev/null +++ b/Documentation/acpi/method-tracing.txt @@ -0,0 +1,192 @@ +ACPICA Trace Facility + +Copyright (C) 2015, Intel Corporation +Author: Lv Zheng <lv.zheng@intel.com> + + +Abstract: + +This document describes the functions and the interfaces of the method +tracing facility. + +1. Functionalities and usage examples: + + ACPICA provides method tracing capability. And two functions are + currently implemented using this capability. + + A. Log reducer + ACPICA subsystem provides debugging outputs when CONFIG_ACPI_DEBUG is + enabled. The debugging messages which are deployed via + ACPI_DEBUG_PRINT() macro can be reduced at 2 levels - per-component + level (known as debug layer, configured via + /sys/module/acpi/parameters/debug_layer) and per-type level (known as + debug level, configured via /sys/module/acpi/parameters/debug_level). + + But when the particular layer/level is applied to the control method + evaluations, the quantity of the debugging outputs may still be too + large to be put into the kernel log buffer. The idea thus is worked out + to only enable the particular debug layer/level (normally more detailed) + logs when the control method evaluation is started, and disable the + detailed logging when the control method evaluation is stopped. + + The following command examples illustrate the usage of the "log reducer" + functionality: + a. Filter out the debug layer/level matched logs when control methods + are being evaluated: + # cd /sys/module/acpi/parameters + # echo "0xXXXXXXXX" > trace_debug_layer + # echo "0xYYYYYYYY" > trace_debug_level + # echo "enable" > trace_state + b. Filter out the debug layer/level matched logs when the specified + control method is being evaluated: + # cd /sys/module/acpi/parameters + # echo "0xXXXXXXXX" > trace_debug_layer + # echo "0xYYYYYYYY" > trace_debug_level + # echo "\PPPP.AAAA.TTTT.HHHH" > trace_method_name + # echo "method" > /sys/module/acpi/parameters/trace_state + c. Filter out the debug layer/level matched logs when the specified + control method is being evaluated for the first time: + # cd /sys/module/acpi/parameters + # echo "0xXXXXXXXX" > trace_debug_layer + # echo "0xYYYYYYYY" > trace_debug_level + # echo "\PPPP.AAAA.TTTT.HHHH" > trace_method_name + # echo "method-once" > /sys/module/acpi/parameters/trace_state + Where: + 0xXXXXXXXX/0xYYYYYYYY: Refer to Documentation/acpi/debug.txt for + possible debug layer/level masking values. + \PPPP.AAAA.TTTT.HHHH: Full path of a control method that can be found + in the ACPI namespace. It needn't be an entry + of a control method evaluation. + + B. AML tracer + + There are special log entries added by the method tracing facility at + the "trace points" the AML interpreter starts/stops to execute a control + method, or an AML opcode. Note that the format of the log entries are + subject to change: + [ 0.186427] exdebug-0398 ex_trace_point : Method Begin [0xf58394d8:\_SB.PCI0.LPCB.ECOK] execution. + [ 0.186630] exdebug-0398 ex_trace_point : Opcode Begin [0xf5905c88:If] execution. + [ 0.186820] exdebug-0398 ex_trace_point : Opcode Begin [0xf5905cc0:LEqual] execution. + [ 0.187010] exdebug-0398 ex_trace_point : Opcode Begin [0xf5905a20:-NamePath-] execution. + [ 0.187214] exdebug-0398 ex_trace_point : Opcode End [0xf5905a20:-NamePath-] execution. + [ 0.187407] exdebug-0398 ex_trace_point : Opcode Begin [0xf5905f60:One] execution. + [ 0.187594] exdebug-0398 ex_trace_point : Opcode End [0xf5905f60:One] execution. + [ 0.187789] exdebug-0398 ex_trace_point : Opcode End [0xf5905cc0:LEqual] execution. + [ 0.187980] exdebug-0398 ex_trace_point : Opcode Begin [0xf5905cc0:Return] execution. + [ 0.188146] exdebug-0398 ex_trace_point : Opcode Begin [0xf5905f60:One] execution. + [ 0.188334] exdebug-0398 ex_trace_point : Opcode End [0xf5905f60:One] execution. + [ 0.188524] exdebug-0398 ex_trace_point : Opcode End [0xf5905cc0:Return] execution. + [ 0.188712] exdebug-0398 ex_trace_point : Opcode End [0xf5905c88:If] execution. + [ 0.188903] exdebug-0398 ex_trace_point : Method End [0xf58394d8:\_SB.PCI0.LPCB.ECOK] execution. + + Developers can utilize these special log entries to track the AML + interpretion, thus can aid issue debugging and performance tuning. Note + that, as the "AML tracer" logs are implemented via ACPI_DEBUG_PRINT() + macro, CONFIG_ACPI_DEBUG is also required to be enabled for enabling + "AML tracer" logs. + + The following command examples illustrate the usage of the "AML tracer" + functionality: + a. Filter out the method start/stop "AML tracer" logs when control + methods are being evaluated: + # cd /sys/module/acpi/parameters + # echo "0x80" > trace_debug_layer + # echo "0x10" > trace_debug_level + # echo "enable" > trace_state + b. Filter out the method start/stop "AML tracer" when the specified + control method is being evaluated: + # cd /sys/module/acpi/parameters + # echo "0x80" > trace_debug_layer + # echo "0x10" > trace_debug_level + # echo "\PPPP.AAAA.TTTT.HHHH" > trace_method_name + # echo "method" > trace_state + c. Filter out the method start/stop "AML tracer" logs when the specified + control method is being evaluated for the first time: + # cd /sys/module/acpi/parameters + # echo "0x80" > trace_debug_layer + # echo "0x10" > trace_debug_level + # echo "\PPPP.AAAA.TTTT.HHHH" > trace_method_name + # echo "method-once" > trace_state + d. Filter out the method/opcode start/stop "AML tracer" when the + specified control method is being evaluated: + # cd /sys/module/acpi/parameters + # echo "0x80" > trace_debug_layer + # echo "0x10" > trace_debug_level + # echo "\PPPP.AAAA.TTTT.HHHH" > trace_method_name + # echo "opcode" > trace_state + e. Filter out the method/opcode start/stop "AML tracer" when the + specified control method is being evaluated for the first time: + # cd /sys/module/acpi/parameters + # echo "0x80" > trace_debug_layer + # echo "0x10" > trace_debug_level + # echo "\PPPP.AAAA.TTTT.HHHH" > trace_method_name + # echo "opcode-opcode" > trace_state + + Note that all above method tracing facility related module parameters can + be used as the boot parameters, for example: + acpi.trace_debug_layer=0x80 acpi.trace_debug_level=0x10 \ + acpi.trace_method_name=\_SB.LID0._LID acpi.trace_state=opcode-once + +2. Interface descriptions: + + All method tracing functions can be configured via ACPI module + parameters that are accessible at /sys/module/acpi/parameters/: + + trace_method_name + The full path of the AML method that the user wants to trace. + Note that the full path shouldn't contain the trailing "_"s in its + name segments but may contain "\" to form an absolute path. + + trace_debug_layer + The temporary debug_layer used when the tracing feature is enabled. + Using ACPI_EXECUTER (0x80) by default, which is the debug_layer + used to match all "AML tracer" logs. + + trace_debug_level + The temporary debug_level used when the tracing feature is enabled. + Using ACPI_LV_TRACE_POINT (0x10) by default, which is the + debug_level used to match all "AML tracer" logs. + + trace_state + The status of the tracing feature. + Users can enable/disable this debug tracing feature by executing + the following command: + # echo string > /sys/module/acpi/parameters/trace_state + Where "string" should be one of the following: + "disable" + Disable the method tracing feature. + "enable" + Enable the method tracing feature. + ACPICA debugging messages matching + "trace_debug_layer/trace_debug_level" during any method + execution will be logged. + "method" + Enable the method tracing feature. + ACPICA debugging messages matching + "trace_debug_layer/trace_debug_level" during method execution + of "trace_method_name" will be logged. + "method-once" + Enable the method tracing feature. + ACPICA debugging messages matching + "trace_debug_layer/trace_debug_level" during method execution + of "trace_method_name" will be logged only once. + "opcode" + Enable the method tracing feature. + ACPICA debugging messages matching + "trace_debug_layer/trace_debug_level" during method/opcode + execution of "trace_method_name" will be logged. + "opcode-once" + Enable the method tracing feature. + ACPICA debugging messages matching + "trace_debug_layer/trace_debug_level" during method/opcode + execution of "trace_method_name" will be logged only once. + Note that, the difference between the "enable" and other feature + enabling options are: + 1. When "enable" is specified, since + "trace_debug_layer/trace_debug_level" shall apply to all control + method evaluations, after configuring "trace_state" to "enable", + "trace_method_name" will be reset to NULL. + 2. When "method/opcode" is specified, if + "trace_method_name" is NULL when "trace_state" is configured to + these options, the "trace_debug_layer/trace_debug_level" will + apply to all control method evaluations. diff --git a/Documentation/acpi/namespace.txt b/Documentation/acpi/namespace.txt new file mode 100644 index 000000000..1860cb386 --- /dev/null +++ b/Documentation/acpi/namespace.txt @@ -0,0 +1,388 @@ +ACPI Device Tree - Representation of ACPI Namespace + +Copyright (C) 2013, Intel Corporation +Author: Lv Zheng <lv.zheng@intel.com> + + +Abstract: + +The Linux ACPI subsystem converts ACPI namespace objects into a Linux +device tree under the /sys/devices/LNXSYSTEM:00 and updates it upon +receiving ACPI hotplug notification events. For each device object in this +hierarchy there is a corresponding symbolic link in the +/sys/bus/acpi/devices. +This document illustrates the structure of the ACPI device tree. + + +Credit: + +Thanks for the help from Zhang Rui <rui.zhang@intel.com> and Rafael J. +Wysocki <rafael.j.wysocki@intel.com>. + + +1. ACPI Definition Blocks + + The ACPI firmware sets up RSDP (Root System Description Pointer) in the + system memory address space pointing to the XSDT (Extended System + Description Table). The XSDT always points to the FADT (Fixed ACPI + Description Table) using its first entry, the data within the FADT + includes various fixed-length entries that describe fixed ACPI features + of the hardware. The FADT contains a pointer to the DSDT + (Differentiated System Descripition Table). The XSDT also contains + entries pointing to possibly multiple SSDTs (Secondary System + Description Table). + + The DSDT and SSDT data is organized in data structures called definition + blocks that contain definitions of various objects, including ACPI + control methods, encoded in AML (ACPI Machine Language). The data block + of the DSDT along with the contents of SSDTs represents a hierarchical + data structure called the ACPI namespace whose topology reflects the + structure of the underlying hardware platform. + + The relationships between ACPI System Definition Tables described above + are illustrated in the following diagram. + + +---------+ +-------+ +--------+ +------------------------+ + | RSDP | +->| XSDT | +->| FADT | | +-------------------+ | + +---------+ | +-------+ | +--------+ +-|->| DSDT | | + | Pointer | | | Entry |-+ | ...... | | | +-------------------+ | + +---------+ | +-------+ | X_DSDT |--+ | | Definition Blocks | | + | Pointer |-+ | ..... | | ...... | | +-------------------+ | + +---------+ +-------+ +--------+ | +-------------------+ | + | Entry |------------------|->| SSDT | | + +- - - -+ | +-------------------| | + | Entry | - - - - - - - -+ | | Definition Blocks | | + +- - - -+ | | +-------------------+ | + | | +- - - - - - - - - -+ | + +-|->| SSDT | | + | +-------------------+ | + | | Definition Blocks | | + | +- - - - - - - - - -+ | + +------------------------+ + | + OSPM Loading | + \|/ + +----------------+ + | ACPI Namespace | + +----------------+ + + Figure 1. ACPI Definition Blocks + + NOTE: RSDP can also contain a pointer to the RSDT (Root System + Description Table). Platforms provide RSDT to enable + compatibility with ACPI 1.0 operating systems. The OS is expected + to use XSDT, if present. + + +2. Example ACPI Namespace + + All definition blocks are loaded into a single namespace. The namespace + is a hierarchy of objects identified by names and paths. + The following naming conventions apply to object names in the ACPI + namespace: + 1. All names are 32 bits long. + 2. The first byte of a name must be one of 'A' - 'Z', '_'. + 3. Each of the remaining bytes of a name must be one of 'A' - 'Z', '0' + - '9', '_'. + 4. Names starting with '_' are reserved by the ACPI specification. + 5. The '\' symbol represents the root of the namespace (i.e. names + prepended with '\' are relative to the namespace root). + 6. The '^' symbol represents the parent of the current namespace node + (i.e. names prepended with '^' are relative to the parent of the + current namespace node). + + The figure below shows an example ACPI namespace. + + +------+ + | \ | Root + +------+ + | + | +------+ + +-| _PR | Scope(_PR): the processor namespace + | +------+ + | | + | | +------+ + | +-| CPU0 | Processor(CPU0): the first processor + | +------+ + | + | +------+ + +-| _SB | Scope(_SB): the system bus namespace + | +------+ + | | + | | +------+ + | +-| LID0 | Device(LID0); the lid device + | | +------+ + | | | + | | | +------+ + | | +-| _HID | Name(_HID, "PNP0C0D"): the hardware ID + | | | +------+ + | | | + | | | +------+ + | | +-| _STA | Method(_STA): the status control method + | | +------+ + | | + | | +------+ + | +-| PCI0 | Device(PCI0); the PCI root bridge + | +------+ + | | + | | +------+ + | +-| _HID | Name(_HID, "PNP0A08"): the hardware ID + | | +------+ + | | + | | +------+ + | +-| _CID | Name(_CID, "PNP0A03"): the compatible ID + | | +------+ + | | + | | +------+ + | +-| RP03 | Scope(RP03): the PCI0 power scope + | | +------+ + | | | + | | | +------+ + | | +-| PXP3 | PowerResource(PXP3): the PCI0 power resource + | | +------+ + | | + | | +------+ + | +-| GFX0 | Device(GFX0): the graphics adapter + | +------+ + | | + | | +------+ + | +-| _ADR | Name(_ADR, 0x00020000): the PCI bus address + | | +------+ + | | + | | +------+ + | +-| DD01 | Device(DD01): the LCD output device + | +------+ + | | + | | +------+ + | +-| _BCL | Method(_BCL): the backlight control method + | +------+ + | + | +------+ + +-| _TZ | Scope(_TZ): the thermal zone namespace + | +------+ + | | + | | +------+ + | +-| FN00 | PowerResource(FN00): the FAN0 power resource + | | +------+ + | | + | | +------+ + | +-| FAN0 | Device(FAN0): the FAN0 cooling device + | | +------+ + | | | + | | | +------+ + | | +-| _HID | Name(_HID, "PNP0A0B"): the hardware ID + | | +------+ + | | + | | +------+ + | +-| TZ00 | ThermalZone(TZ00); the FAN thermal zone + | +------+ + | + | +------+ + +-| _GPE | Scope(_GPE): the GPE namespace + +------+ + + Figure 2. Example ACPI Namespace + + +3. Linux ACPI Device Objects + + The Linux kernel's core ACPI subsystem creates struct acpi_device + objects for ACPI namespace objects representing devices, power resources + processors, thermal zones. Those objects are exported to user space via + sysfs as directories in the subtree under /sys/devices/LNXSYSTM:00. The + format of their names is <bus_id:instance>, where 'bus_id' refers to the + ACPI namespace representation of the given object and 'instance' is used + for distinguishing different object of the same 'bus_id' (it is + two-digit decimal representation of an unsigned integer). + + The value of 'bus_id' depends on the type of the object whose name it is + part of as listed in the table below. + + +---+-----------------+-------+----------+ + | | Object/Feature | Table | bus_id | + +---+-----------------+-------+----------+ + | N | Root | xSDT | LNXSYSTM | + +---+-----------------+-------+----------+ + | N | Device | xSDT | _HID | + +---+-----------------+-------+----------+ + | N | Processor | xSDT | LNXCPU | + +---+-----------------+-------+----------+ + | N | ThermalZone | xSDT | LNXTHERM | + +---+-----------------+-------+----------+ + | N | PowerResource | xSDT | LNXPOWER | + +---+-----------------+-------+----------+ + | N | Other Devices | xSDT | device | + +---+-----------------+-------+----------+ + | F | PWR_BUTTON | FADT | LNXPWRBN | + +---+-----------------+-------+----------+ + | F | SLP_BUTTON | FADT | LNXSLPBN | + +---+-----------------+-------+----------+ + | M | Video Extension | xSDT | LNXVIDEO | + +---+-----------------+-------+----------+ + | M | ATA Controller | xSDT | LNXIOBAY | + +---+-----------------+-------+----------+ + | M | Docking Station | xSDT | LNXDOCK | + +---+-----------------+-------+----------+ + + Table 1. ACPI Namespace Objects Mapping + + The following rules apply when creating struct acpi_device objects on + the basis of the contents of ACPI System Description Tables (as + indicated by the letter in the first column and the notation in the + second column of the table above): + N: + The object's source is an ACPI namespace node (as indicated by the + named object's type in the second column). In that case the object's + directory in sysfs will contain the 'path' attribute whose value is + the full path to the node from the namespace root. + F: + The struct acpi_device object is created for a fixed hardware + feature (as indicated by the fixed feature flag's name in the second + column), so its sysfs directory will not contain the 'path' + attribute. + M: + The struct acpi_device object is created for an ACPI namespace node + with specific control methods (as indicated by the ACPI defined + device's type in the second column). The 'path' attribute containing + its namespace path will be present in its sysfs directory. For + example, if the _BCL method is present for an ACPI namespace node, a + struct acpi_device object with LNXVIDEO 'bus_id' will be created for + it. + + The third column of the above table indicates which ACPI System + Description Tables contain information used for the creation of the + struct acpi_device objects represented by the given row (xSDT means DSDT + or SSDT). + + The forth column of the above table indicates the 'bus_id' generation + rule of the struct acpi_device object: + _HID: + _HID in the last column of the table means that the object's bus_id + is derived from the _HID/_CID identification objects present under + the corresponding ACPI namespace node. The object's sysfs directory + will then contain the 'hid' and 'modalias' attributes that can be + used to retrieve the _HID and _CIDs of that object. + LNXxxxxx: + The 'modalias' attribute is also present for struct acpi_device + objects having bus_id of the "LNXxxxxx" form (pseudo devices), in + which cases it contains the bus_id string itself. + device: + 'device' in the last column of the table indicates that the object's + bus_id cannot be determined from _HID/_CID of the corresponding + ACPI namespace node, although that object represents a device (for + example, it may be a PCI device with _ADR defined and without _HID + or _CID). In that case the string 'device' will be used as the + object's bus_id. + + +4. Linux ACPI Physical Device Glue + + ACPI device (i.e. struct acpi_device) objects may be linked to other + objects in the Linux' device hierarchy that represent "physical" devices + (for example, devices on the PCI bus). If that happens, it means that + the ACPI device object is a "companion" of a device otherwise + represented in a different way and is used (1) to provide configuration + information on that device which cannot be obtained by other means and + (2) to do specific things to the device with the help of its ACPI + control methods. One ACPI device object may be linked this way to + multiple "physical" devices. + + If an ACPI device object is linked to a "physical" device, its sysfs + directory contains the "physical_node" symbolic link to the sysfs + directory of the target device object. In turn, the target device's + sysfs directory will then contain the "firmware_node" symbolic link to + the sysfs directory of the companion ACPI device object. + The linking mechanism relies on device identification provided by the + ACPI namespace. For example, if there's an ACPI namespace object + representing a PCI device (i.e. a device object under an ACPI namespace + object representing a PCI bridge) whose _ADR returns 0x00020000 and the + bus number of the parent PCI bridge is 0, the sysfs directory + representing the struct acpi_device object created for that ACPI + namespace object will contain the 'physical_node' symbolic link to the + /sys/devices/pci0000:00/0000:00:02:0/ sysfs directory of the + corresponding PCI device. + + The linking mechanism is generally bus-specific. The core of its + implementation is located in the drivers/acpi/glue.c file, but there are + complementary parts depending on the bus types in question located + elsewhere. For example, the PCI-specific part of it is located in + drivers/pci/pci-acpi.c. + + +5. Example Linux ACPI Device Tree + + The sysfs hierarchy of struct acpi_device objects corresponding to the + example ACPI namespace illustrated in Figure 2 with the addition of + fixed PWR_BUTTON/SLP_BUTTON devices is shown below. + + +--------------+---+-----------------+ + | LNXSYSTEM:00 | \ | acpi:LNXSYSTEM: | + +--------------+---+-----------------+ + | + | +-------------+-----+----------------+ + +-| LNXPWRBN:00 | N/A | acpi:LNXPWRBN: | + | +-------------+-----+----------------+ + | + | +-------------+-----+----------------+ + +-| LNXSLPBN:00 | N/A | acpi:LNXSLPBN: | + | +-------------+-----+----------------+ + | + | +-----------+------------+--------------+ + +-| LNXCPU:00 | \_PR_.CPU0 | acpi:LNXCPU: | + | +-----------+------------+--------------+ + | + | +-------------+-------+----------------+ + +-| LNXSYBUS:00 | \_SB_ | acpi:LNXSYBUS: | + | +-------------+-------+----------------+ + | | + | | +- - - - - - - +- - - - - - +- - - - - - - -+ + | +-| PNP0C0D:00 | \_SB_.LID0 | acpi:PNP0C0D: | + | | +- - - - - - - +- - - - - - +- - - - - - - -+ + | | + | | +------------+------------+-----------------------+ + | +-| PNP0A08:00 | \_SB_.PCI0 | acpi:PNP0A08:PNP0A03: | + | +------------+------------+-----------------------+ + | | + | | +-----------+-----------------+-----+ + | +-| device:00 | \_SB_.PCI0.RP03 | N/A | + | | +-----------+-----------------+-----+ + | | | + | | | +-------------+----------------------+----------------+ + | | +-| LNXPOWER:00 | \_SB_.PCI0.RP03.PXP3 | acpi:LNXPOWER: | + | | +-------------+----------------------+----------------+ + | | + | | +-------------+-----------------+----------------+ + | +-| LNXVIDEO:00 | \_SB_.PCI0.GFX0 | acpi:LNXVIDEO: | + | +-------------+-----------------+----------------+ + | | + | | +-----------+-----------------+-----+ + | +-| device:01 | \_SB_.PCI0.DD01 | N/A | + | +-----------+-----------------+-----+ + | + | +-------------+-------+----------------+ + +-| LNXSYBUS:01 | \_TZ_ | acpi:LNXSYBUS: | + +-------------+-------+----------------+ + | + | +-------------+------------+----------------+ + +-| LNXPOWER:0a | \_TZ_.FN00 | acpi:LNXPOWER: | + | +-------------+------------+----------------+ + | + | +------------+------------+---------------+ + +-| PNP0C0B:00 | \_TZ_.FAN0 | acpi:PNP0C0B: | + | +------------+------------+---------------+ + | + | +-------------+------------+----------------+ + +-| LNXTHERM:00 | \_TZ_.TZ00 | acpi:LNXTHERM: | + +-------------+------------+----------------+ + + Figure 3. Example Linux ACPI Device Tree + + NOTE: Each node is represented as "object/path/modalias", where: + 1. 'object' is the name of the object's directory in sysfs. + 2. 'path' is the ACPI namespace path of the corresponding + ACPI namespace object, as returned by the object's 'path' + sysfs attribute. + 3. 'modalias' is the value of the object's 'modalias' sysfs + attribute (as described earlier in this document). + NOTE: N/A indicates the device object does not have the 'path' or the + 'modalias' attribute. diff --git a/Documentation/acpi/osi.txt b/Documentation/acpi/osi.txt new file mode 100644 index 000000000..50cde0ceb --- /dev/null +++ b/Documentation/acpi/osi.txt @@ -0,0 +1,187 @@ +ACPI _OSI and _REV methods +-------------------------- + +An ACPI BIOS can use the "Operating System Interfaces" method (_OSI) +to find out what the operating system supports. Eg. If BIOS +AML code includes _OSI("XYZ"), the kernel's AML interpreter +can evaluate that method, look to see if it supports 'XYZ' +and answer YES or NO to the BIOS. + +The ACPI _REV method returns the "Revision of the ACPI specification +that OSPM supports" + +This document explains how and why the BIOS and Linux should use these methods. +It also explains how and why they are widely misused. + +How to use _OSI +--------------- + +Linux runs on two groups of machines -- those that are tested by the OEM +to be compatible with Linux, and those that were never tested with Linux, +but where Linux was installed to replace the original OS (Windows or OSX). + +The larger group is the systems tested to run only Windows. Not only that, +but many were tested to run with just one specific version of Windows. +So even though the BIOS may use _OSI to query what version of Windows is running, +only a single path through the BIOS has actually been tested. +Experience shows that taking untested paths through the BIOS +exposes Linux to an entire category of BIOS bugs. +For this reason, Linux _OSI defaults must continue to claim compatibility +with all versions of Windows. + +But Linux isn't actually compatible with Windows, and the Linux community +has also been hurt with regressions when Linux adds the latest version of +Windows to its list of _OSI strings. So it is possible that additional strings +will be more thoroughly vetted before shipping upstream in the future. +But it is likely that they will all eventually be added. + +What should an OEM do if they want to support Linux and Windows +using the same BIOS image? Often they need to do something different +for Linux to deal with how Linux is different from Windows. +Here the BIOS should ask exactly what it wants to know: + +_OSI("Linux-OEM-my_interface_name") +where 'OEM' is needed if this is an OEM-specific hook, +and 'my_interface_name' describes the hook, which could be a +quirk, a bug, or a bug-fix. + +In addition, the OEM should send a patch to upstream Linux +via the linux-acpi@vger.kernel.org mailing list. When that patch +is checked into Linux, the OS will answer "YES" when the BIOS +on the OEM's system uses _OSI to ask if the interface is supported +by the OS. Linux distributors can back-port that patch for Linux +pre-installs, and it will be included by all distributions that +re-base to upstream. If the distribution can not update the kernel binary, +they can also add an acpi_osi=Linux-OEM-my_interface_name +cmdline parameter to the boot loader, as needed. + +If the string refers to a feature where the upstream kernel +eventually grows support, a patch should be sent to remove +the string when that support is added to the kernel. + +That was easy. Read on, to find out how to do it wrong. + +Before _OSI, there was _OS +-------------------------- + +ACPI 1.0 specified "_OS" as an +"object that evaluates to a string that identifies the operating system." + +The ACPI BIOS flow would include an evaluation of _OS, and the AML +interpreter in the kernel would return to it a string identifying the OS: + +Windows 98, SE: "Microsoft Windows" +Windows ME: "Microsoft WindowsME:Millenium Edition" +Windows NT: "Microsoft Windows NT" + +The idea was on a platform tasked with running multiple OS's, +the BIOS could use _OS to enable devices that an OS +might support, or enable quirks or bug workarounds +necessary to make the platform compatible with that pre-existing OS. + +But _OS had fundamental problems. First, the BIOS needed to know the name +of every possible version of the OS that would run on it, and needed to know +all the quirks of those OS's. Certainly it would make more sense +for the BIOS to ask *specific* things of the OS, such +"do you support a specific interface", and thus in ACPI 3.0, +_OSI was born to replace _OS. + +_OS was abandoned, though even today, many BIOS look for +_OS "Microsoft Windows NT", though it seems somewhat far-fetched +that anybody would install those old operating systems +over what came with the machine. + +Linux answers "Microsoft Windows NT" to please that BIOS idiom. +That is the *only* viable strategy, as that is what modern Windows does, +and so doing otherwise could steer the BIOS down an untested path. + +_OSI is born, and immediately misused +-------------------------------------- + +With _OSI, the *BIOS* provides the string describing an interface, +and asks the OS: "YES/NO, are you compatible with this interface?" + +eg. _OSI("3.0 Thermal Model") would return TRUE if the OS knows how +to deal with the thermal extensions made to the ACPI 3.0 specification. +An old OS that doesn't know about those extensions would answer FALSE, +and a new OS may be able to return TRUE. + +For an OS-specific interface, the ACPI spec said that the BIOS and the OS +were to agree on a string of the form such as "Windows-interface_name". + +But two bad things happened. First, the Windows ecosystem used _OSI +not as designed, but as a direct replacement for _OS -- identifying +the OS version, rather than an OS supported interface. Indeed, right +from the start, the ACPI 3.0 spec itself codified this misuse +in example code using _OSI("Windows 2001"). + +This misuse was adopted and continues today. + +Linux had no choice but to also return TRUE to _OSI("Windows 2001") +and its successors. To do otherwise would virtually guarantee breaking +a BIOS that has been tested only with that _OSI returning TRUE. + +This strategy is problematic, as Linux is never completely compatible with +the latest version of Windows, and sometimes it takes more than a year +to iron out incompatibilities. + +Not to be out-done, the Linux community made things worse by returning TRUE +to _OSI("Linux"). Doing so is even worse than the Windows misuse +of _OSI, as "Linux" does not even contain any version information. +_OSI("Linux") led to some BIOS' malfunctioning due to BIOS writer's +using it in untested BIOS flows. But some OEM's used _OSI("Linux") +in tested flows to support real Linux features. In 2009, Linux +removed _OSI("Linux"), and added a cmdline parameter to restore it +for legacy systems still needed it. Further a BIOS_BUG warning prints +for all BIOS's that invoke it. + +No BIOS should use _OSI("Linux"). + +The result is a strategy for Linux to maximize compatibility with +ACPI BIOS that are tested on Windows machines. There is a real risk +of over-stating that compatibility; but the alternative has often been +catastrophic failure resulting from the BIOS taking paths that +were never validated under *any* OS. + +Do not use _REV +--------------- + +Since _OSI("Linux") went away, some BIOS writers used _REV +to support Linux and Windows differences in the same BIOS. + +_REV was defined in ACPI 1.0 to return the version of ACPI +supported by the OS and the OS AML interpreter. + +Modern Windows returns _REV = 2. Linux used ACPI_CA_SUPPORT_LEVEL, +which would increment, based on the version of the spec supported. + +Unfortunately, _REV was also misused. eg. some BIOS would check +for _REV = 3, and do something for Linux, but when Linux returned +_REV = 4, that support broke. + +In response to this problem, Linux returns _REV = 2 always, +from mid-2015 onward. The ACPI specification will also be updated +to reflect that _REV is deprecated, and always returns 2. + +Apple Mac and _OSI("Darwin") +---------------------------- + +On Apple's Mac platforms, the ACPI BIOS invokes _OSI("Darwin") +to determine if the machine is running Apple OSX. + +Like Linux's _OSI("*Windows*") strategy, Linux defaults to +answering YES to _OSI("Darwin") to enable full access +to the hardware and validated BIOS paths seen by OSX. +Just like on Windows-tested platforms, this strategy has risks. + +Starting in Linux-3.18, the kernel answered YES to _OSI("Darwin") +for the purpose of enabling Mac Thunderbolt support. Further, +if the kernel noticed _OSI("Darwin") being invoked, it additionally +disabled all _OSI("*Windows*") to keep poorly written Mac BIOS +from going down untested combinations of paths. + +The Linux-3.18 change in default caused power regressions on Mac +laptops, and the 3.18 implementation did not allow changing +the default via cmdline "acpi_osi=!Darwin". Linux-4.7 fixed +the ability to use acpi_osi=!Darwin as a workaround, and +we hope to see Mac Thunderbolt power management support in Linux-4.11. diff --git a/Documentation/acpi/scan_handlers.txt b/Documentation/acpi/scan_handlers.txt new file mode 100644 index 000000000..3246ccf15 --- /dev/null +++ b/Documentation/acpi/scan_handlers.txt @@ -0,0 +1,77 @@ +ACPI Scan Handlers + +Copyright (C) 2012, Intel Corporation +Author: Rafael J. Wysocki <rafael.j.wysocki@intel.com> + +During system initialization and ACPI-based device hot-add, the ACPI namespace +is scanned in search of device objects that generally represent various pieces +of hardware. This causes a struct acpi_device object to be created and +registered with the driver core for every device object in the ACPI namespace +and the hierarchy of those struct acpi_device objects reflects the namespace +layout (i.e. parent device objects in the namespace are represented by parent +struct acpi_device objects and analogously for their children). Those struct +acpi_device objects are referred to as "device nodes" in what follows, but they +should not be confused with struct device_node objects used by the Device Trees +parsing code (although their role is analogous to the role of those objects). + +During ACPI-based device hot-remove device nodes representing pieces of hardware +being removed are unregistered and deleted. + +The core ACPI namespace scanning code in drivers/acpi/scan.c carries out basic +initialization of device nodes, such as retrieving common configuration +information from the device objects represented by them and populating them with +appropriate data, but some of them require additional handling after they have +been registered. For example, if the given device node represents a PCI host +bridge, its registration should cause the PCI bus under that bridge to be +enumerated and PCI devices on that bus to be registered with the driver core. +Similarly, if the device node represents a PCI interrupt link, it is necessary +to configure that link so that the kernel can use it. + +Those additional configuration tasks usually depend on the type of the hardware +component represented by the given device node which can be determined on the +basis of the device node's hardware ID (HID). They are performed by objects +called ACPI scan handlers represented by the following structure: + +struct acpi_scan_handler { + const struct acpi_device_id *ids; + struct list_head list_node; + int (*attach)(struct acpi_device *dev, const struct acpi_device_id *id); + void (*detach)(struct acpi_device *dev); +}; + +where ids is the list of IDs of device nodes the given handler is supposed to +take care of, list_node is the hook to the global list of ACPI scan handlers +maintained by the ACPI core and the .attach() and .detach() callbacks are +executed, respectively, after registration of new device nodes and before +unregistration of device nodes the handler attached to previously. + +The namespace scanning function, acpi_bus_scan(), first registers all of the +device nodes in the given namespace scope with the driver core. Then, it tries +to match a scan handler against each of them using the ids arrays of the +available scan handlers. If a matching scan handler is found, its .attach() +callback is executed for the given device node. If that callback returns 1, +that means that the handler has claimed the device node and is now responsible +for carrying out any additional configuration tasks related to it. It also will +be responsible for preparing the device node for unregistration in that case. +The device node's handler field is then populated with the address of the scan +handler that has claimed it. + +If the .attach() callback returns 0, it means that the device node is not +interesting to the given scan handler and may be matched against the next scan +handler in the list. If it returns a (negative) error code, that means that +the namespace scan should be terminated due to a serious error. The error code +returned should then reflect the type of the error. + +The namespace trimming function, acpi_bus_trim(), first executes .detach() +callbacks from the scan handlers of all device nodes in the given namespace +scope (if they have scan handlers). Next, it unregisters all of the device +nodes in that scope. + +ACPI scan handlers can be added to the list maintained by the ACPI core with the +help of the acpi_scan_add_handler() function taking a pointer to the new scan +handler as an argument. The order in which scan handlers are added to the list +is the order in which they are matched against device nodes during namespace +scans. + +All scan handles must be added to the list before acpi_bus_scan() is run for the +first time and they cannot be removed from it. diff --git a/Documentation/acpi/ssdt-overlays.txt b/Documentation/acpi/ssdt-overlays.txt new file mode 100644 index 000000000..5ae13f161 --- /dev/null +++ b/Documentation/acpi/ssdt-overlays.txt @@ -0,0 +1,172 @@ + +In order to support ACPI open-ended hardware configurations (e.g. development +boards) we need a way to augment the ACPI configuration provided by the firmware +image. A common example is connecting sensors on I2C / SPI buses on development +boards. + +Although this can be accomplished by creating a kernel platform driver or +recompiling the firmware image with updated ACPI tables, neither is practical: +the former proliferates board specific kernel code while the latter requires +access to firmware tools which are often not publicly available. + +Because ACPI supports external references in AML code a more practical +way to augment firmware ACPI configuration is by dynamically loading +user defined SSDT tables that contain the board specific information. + +For example, to enumerate a Bosch BMA222E accelerometer on the I2C bus of the +Minnowboard MAX development board exposed via the LSE connector [1], the +following ASL code can be used: + +DefinitionBlock ("minnowmax.aml", "SSDT", 1, "Vendor", "Accel", 0x00000003) +{ + External (\_SB.I2C6, DeviceObj) + + Scope (\_SB.I2C6) + { + Device (STAC) + { + Name (_ADR, Zero) + Name (_HID, "BMA222E") + + Method (_CRS, 0, Serialized) + { + Name (RBUF, ResourceTemplate () + { + I2cSerialBus (0x0018, ControllerInitiated, 0x00061A80, + AddressingMode7Bit, "\\_SB.I2C6", 0x00, + ResourceConsumer, ,) + GpioInt (Edge, ActiveHigh, Exclusive, PullDown, 0x0000, + "\\_SB.GPO2", 0x00, ResourceConsumer, , ) + { // Pin list + 0 + } + }) + Return (RBUF) + } + } + } +} + +which can then be compiled to AML binary format: + +$ iasl minnowmax.asl + +Intel ACPI Component Architecture +ASL Optimizing Compiler version 20140214-64 [Mar 29 2014] +Copyright (c) 2000 - 2014 Intel Corporation + +ASL Input: minnomax.asl - 30 lines, 614 bytes, 7 keywords +AML Output: minnowmax.aml - 165 bytes, 6 named objects, 1 executable opcodes + +[1] http://wiki.minnowboard.org/MinnowBoard_MAX#Low_Speed_Expansion_Connector_.28Top.29 + +The resulting AML code can then be loaded by the kernel using one of the methods +below. + +== Loading ACPI SSDTs from initrd == + +This option allows loading of user defined SSDTs from initrd and it is useful +when the system does not support EFI or when there is not enough EFI storage. + +It works in a similar way with initrd based ACPI tables override/upgrade: SSDT +aml code must be placed in the first, uncompressed, initrd under the +"kernel/firmware/acpi" path. Multiple files can be used and this will translate +in loading multiple tables. Only SSDT and OEM tables are allowed. See +initrd_table_override.txt for more details. + +Here is an example: + +# Add the raw ACPI tables to an uncompressed cpio archive. +# They must be put into a /kernel/firmware/acpi directory inside the +# cpio archive. +# The uncompressed cpio archive must be the first. +# Other, typically compressed cpio archives, must be +# concatenated on top of the uncompressed one. +mkdir -p kernel/firmware/acpi +cp ssdt.aml kernel/firmware/acpi + +# Create the uncompressed cpio archive and concatenate the original initrd +# on top: +find kernel | cpio -H newc --create > /boot/instrumented_initrd +cat /boot/initrd >>/boot/instrumented_initrd + +== Loading ACPI SSDTs from EFI variables == + +This is the preferred method, when EFI is supported on the platform, because it +allows a persistent, OS independent way of storing the user defined SSDTs. There +is also work underway to implement EFI support for loading user defined SSDTs +and using this method will make it easier to convert to the EFI loading +mechanism when that will arrive. + +In order to load SSDTs from an EFI variable the efivar_ssdt kernel command line +parameter can be used. The argument for the option is the variable name to +use. If there are multiple variables with the same name but with different +vendor GUIDs, all of them will be loaded. + +In order to store the AML code in an EFI variable the efivarfs filesystem can be +used. It is enabled and mounted by default in /sys/firmware/efi/efivars in all +recent distribution. + +Creating a new file in /sys/firmware/efi/efivars will automatically create a new +EFI variable. Updating a file in /sys/firmware/efi/efivars will update the EFI +variable. Please note that the file name needs to be specially formatted as +"Name-GUID" and that the first 4 bytes in the file (little-endian format) +represent the attributes of the EFI variable (see EFI_VARIABLE_MASK in +include/linux/efi.h). Writing to the file must also be done with one write +operation. + +For example, you can use the following bash script to create/update an EFI +variable with the content from a given file: + +#!/bin/sh -e + +while ! [ -z "$1" ]; do + case "$1" in + "-f") filename="$2"; shift;; + "-g") guid="$2"; shift;; + *) name="$1";; + esac + shift +done + +usage() +{ + echo "Syntax: ${0##*/} -f filename [ -g guid ] name" + exit 1 +} + +[ -n "$name" -a -f "$filename" ] || usage + +EFIVARFS="/sys/firmware/efi/efivars" + +[ -d "$EFIVARFS" ] || exit 2 + +if stat -tf $EFIVARFS | grep -q -v de5e81e4; then + mount -t efivarfs none $EFIVARFS +fi + +# try to pick up an existing GUID +[ -n "$guid" ] || guid=$(find "$EFIVARFS" -name "$name-*" | head -n1 | cut -f2- -d-) + +# use a randomly generated GUID +[ -n "$guid" ] || guid="$(cat /proc/sys/kernel/random/uuid)" + +# efivarfs expects all of the data in one write +tmp=$(mktemp) +/bin/echo -ne "\007\000\000\000" | cat - $filename > $tmp +dd if=$tmp of="$EFIVARFS/$name-$guid" bs=$(stat -c %s $tmp) +rm $tmp + +== Loading ACPI SSDTs from configfs == + +This option allows loading of user defined SSDTs from userspace via the configfs +interface. The CONFIG_ACPI_CONFIGFS option must be select and configfs must be +mounted. In the following examples, we assume that configfs has been mounted in +/config. + +New tables can be loading by creating new directories in /config/acpi/table/ and +writing the SSDT aml code in the aml attribute: + +cd /config/acpi/table +mkdir my_ssdt +cat ~/ssdt.aml > my_ssdt/aml diff --git a/Documentation/acpi/video_extension.txt b/Documentation/acpi/video_extension.txt new file mode 100644 index 000000000..79bf6a492 --- /dev/null +++ b/Documentation/acpi/video_extension.txt @@ -0,0 +1,106 @@ +ACPI video extensions +~~~~~~~~~~~~~~~~~~~~~ + +This driver implement the ACPI Extensions For Display Adapters for +integrated graphics devices on motherboard, as specified in ACPI 2.0 +Specification, Appendix B, allowing to perform some basic control like +defining the video POST device, retrieving EDID information or to +setup a video output, etc. Note that this is an ref. implementation +only. It may or may not work for your integrated video device. + +The ACPI video driver does 3 things regarding backlight control: + +1 Export a sysfs interface for user space to control backlight level + +If the ACPI table has a video device, and acpi_backlight=vendor kernel +command line is not present, the driver will register a backlight device +and set the required backlight operation structure for it for the sysfs +interface control. For every registered class device, there will be a +directory named acpi_videoX under /sys/class/backlight. + +The backlight sysfs interface has a standard definition here: +Documentation/ABI/stable/sysfs-class-backlight. + +And what ACPI video driver does is: +actual_brightness: on read, control method _BQC will be evaluated to +get the brightness level the firmware thinks it is at; +bl_power: not implemented, will set the current brightness instead; +brightness: on write, control method _BCM will run to set the requested +brightness level; +max_brightness: Derived from the _BCL package(see below); +type: firmware + +Note that ACPI video backlight driver will always use index for +brightness, actual_brightness and max_brightness. So if we have +the following _BCL package: + +Method (_BCL, 0, NotSerialized) +{ + Return (Package (0x0C) + { + 0x64, + 0x32, + 0x0A, + 0x14, + 0x1E, + 0x28, + 0x32, + 0x3C, + 0x46, + 0x50, + 0x5A, + 0x64 + }) +} + +The first two levels are for when laptop are on AC or on battery and are +not used by Linux currently. The remaining 10 levels are supported levels +that we can choose from. The applicable index values are from 0 (that +corresponds to the 0x0A brightness value) to 9 (that corresponds to the +0x64 brightness value) inclusive. Each of those index values is regarded +as a "brightness level" indicator. Thus from the user space perspective +the range of available brightness levels is from 0 to 9 (max_brightness) +inclusive. + +2 Notify user space about hotkey event + +There are generally two cases for hotkey event reporting: +i) For some laptops, when user presses the hotkey, a scancode will be + generated and sent to user space through the input device created by + the keyboard driver as a key type input event, with proper remap, the + following key code will appear to user space: + + EV_KEY, KEY_BRIGHTNESSUP + EV_KEY, KEY_BRIGHTNESSDOWN + etc. + +For this case, ACPI video driver does not need to do anything(actually, +it doesn't even know this happened). + +ii) For some laptops, the press of the hotkey will not generate the + scancode, instead, firmware will notify the video device ACPI node + about the event. The event value is defined in the ACPI spec. ACPI + video driver will generate an key type input event according to the + notify value it received and send the event to user space through the + input device it created: + + event keycode + 0x86 KEY_BRIGHTNESSUP + 0x87 KEY_BRIGHTNESSDOWN + etc. + +so this would lead to the same effect as case i) now. + +Once user space tool receives this event, it can modify the backlight +level through the sysfs interface. + +3 Change backlight level in the kernel + +This works for machines covered by case ii) in Section 2. Once the driver +received a notification, it will set the backlight level accordingly. This does +not affect the sending of event to user space, they are always sent to user +space regardless of whether or not the video module controls the backlight level +directly. This behaviour can be controlled through the brightness_switch_enabled +module parameter as documented in admin-guide/kernel-parameters.rst. It is recommended to +disable this behaviour once a GUI environment starts up and wants to have full +control of the backlight level. |