Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
James Seo | 7172 | 99.79% | 4 | 66.67% |
Armin Wolf | 8 | 0.11% | 1 | 16.67% |
Arnd Bergmann | 7 | 0.10% | 1 | 16.67% |
Total | 7187 | 6 |
// SPDX-License-Identifier: GPL-2.0-or-later /* * hwmon driver for HP (and some HP Compaq) business-class computers that * report numeric sensor data via Windows Management Instrumentation (WMI). * * Copyright (C) 2023 James Seo <james@equiv.tech> * * References: * [1] Hewlett-Packard Development Company, L.P., * "HP Client Management Interface Technical White Paper", 2005. [Online]. * Available: https://h20331.www2.hp.com/hpsub/downloads/cmi_whitepaper.pdf * [2] Hewlett-Packard Development Company, L.P., * "HP Retail Manageability", 2012. [Online]. * Available: http://h10032.www1.hp.com/ctg/Manual/c03291135.pdf * [3] Linux Hardware Project, A. Ponomarenko et al., * "linuxhw/ACPI - Collect ACPI table dumps", 2018. [Online]. * Available: https://github.com/linuxhw/ACPI * [4] P. Rohár, "bmfdec - Decompile binary MOF file (BMF) from WMI buffer", * 2017. [Online]. Available: https://github.com/pali/bmfdec * [5] Microsoft Corporation, "Driver-Defined WMI Data Items", 2017. [Online]. * Available: https://learn.microsoft.com/en-us/windows-hardware/drivers/kernel/driver-defined-wmi-data-items */ #include <linux/acpi.h> #include <linux/debugfs.h> #include <linux/hwmon.h> #include <linux/jiffies.h> #include <linux/mutex.h> #include <linux/nls.h> #include <linux/units.h> #include <linux/wmi.h> #define HP_WMI_EVENT_NAMESPACE "root\\WMI" #define HP_WMI_EVENT_CLASS "HPBIOS_BIOSEvent" #define HP_WMI_EVENT_GUID "95F24279-4D7B-4334-9387-ACCDC67EF61C" #define HP_WMI_NUMERIC_SENSOR_GUID "8F1F6435-9F42-42C8-BADC-0E9424F20C9A" #define HP_WMI_PLATFORM_EVENTS_GUID "41227C2D-80E1-423F-8B8E-87E32755A0EB" /* Patterns for recognizing sensors and matching events to channels. */ #define HP_WMI_PATTERN_SYS_TEMP "Chassis Thermal Index" #define HP_WMI_PATTERN_SYS_TEMP2 "System Ambient Temperature" #define HP_WMI_PATTERN_CPU_TEMP "CPU Thermal Index" #define HP_WMI_PATTERN_CPU_TEMP2 "CPU Temperature" #define HP_WMI_PATTERN_TEMP_SENSOR "Thermal Index" #define HP_WMI_PATTERN_TEMP_ALARM "Thermal Critical" #define HP_WMI_PATTERN_INTRUSION_ALARM "Hood Intrusion" #define HP_WMI_PATTERN_FAN_ALARM "Stall" #define HP_WMI_PATTERN_TEMP "Temperature" #define HP_WMI_PATTERN_CPU "CPU" /* These limits are arbitrary. The WMI implementation may vary by system. */ #define HP_WMI_MAX_STR_SIZE 128U #define HP_WMI_MAX_PROPERTIES 32U #define HP_WMI_MAX_INSTANCES 32U enum hp_wmi_type { HP_WMI_TYPE_OTHER = 1, HP_WMI_TYPE_TEMPERATURE = 2, HP_WMI_TYPE_VOLTAGE = 3, HP_WMI_TYPE_CURRENT = 4, HP_WMI_TYPE_AIR_FLOW = 12, HP_WMI_TYPE_INTRUSION = 0xabadb01, /* Custom. */ }; enum hp_wmi_category { HP_WMI_CATEGORY_SENSOR = 3, }; enum hp_wmi_severity { HP_WMI_SEVERITY_UNKNOWN = 0, HP_WMI_SEVERITY_OK = 5, HP_WMI_SEVERITY_DEGRADED_WARNING = 10, HP_WMI_SEVERITY_MINOR_FAILURE = 15, HP_WMI_SEVERITY_MAJOR_FAILURE = 20, HP_WMI_SEVERITY_CRITICAL_FAILURE = 25, HP_WMI_SEVERITY_NON_RECOVERABLE_ERROR = 30, }; enum hp_wmi_status { HP_WMI_STATUS_OK = 2, HP_WMI_STATUS_DEGRADED = 3, HP_WMI_STATUS_STRESSED = 4, HP_WMI_STATUS_PREDICTIVE_FAILURE = 5, HP_WMI_STATUS_ERROR = 6, HP_WMI_STATUS_NON_RECOVERABLE_ERROR = 7, HP_WMI_STATUS_NO_CONTACT = 12, HP_WMI_STATUS_LOST_COMMUNICATION = 13, HP_WMI_STATUS_ABORTED = 14, HP_WMI_STATUS_SUPPORTING_ENTITY_IN_ERROR = 16, /* Occurs combined with one of "OK", "Degraded", and "Error" [1]. */ HP_WMI_STATUS_COMPLETED = 17, }; enum hp_wmi_units { HP_WMI_UNITS_OTHER = 1, HP_WMI_UNITS_DEGREES_C = 2, HP_WMI_UNITS_DEGREES_F = 3, HP_WMI_UNITS_DEGREES_K = 4, HP_WMI_UNITS_VOLTS = 5, HP_WMI_UNITS_AMPS = 6, HP_WMI_UNITS_RPM = 19, }; enum hp_wmi_property { HP_WMI_PROPERTY_NAME = 0, HP_WMI_PROPERTY_DESCRIPTION = 1, HP_WMI_PROPERTY_SENSOR_TYPE = 2, HP_WMI_PROPERTY_OTHER_SENSOR_TYPE = 3, HP_WMI_PROPERTY_OPERATIONAL_STATUS = 4, HP_WMI_PROPERTY_SIZE = 5, HP_WMI_PROPERTY_POSSIBLE_STATES = 6, HP_WMI_PROPERTY_CURRENT_STATE = 7, HP_WMI_PROPERTY_BASE_UNITS = 8, HP_WMI_PROPERTY_UNIT_MODIFIER = 9, HP_WMI_PROPERTY_CURRENT_READING = 10, HP_WMI_PROPERTY_RATE_UNITS = 11, }; static const acpi_object_type hp_wmi_property_map[] = { [HP_WMI_PROPERTY_NAME] = ACPI_TYPE_STRING, [HP_WMI_PROPERTY_DESCRIPTION] = ACPI_TYPE_STRING, [HP_WMI_PROPERTY_SENSOR_TYPE] = ACPI_TYPE_INTEGER, [HP_WMI_PROPERTY_OTHER_SENSOR_TYPE] = ACPI_TYPE_STRING, [HP_WMI_PROPERTY_OPERATIONAL_STATUS] = ACPI_TYPE_INTEGER, [HP_WMI_PROPERTY_SIZE] = ACPI_TYPE_INTEGER, [HP_WMI_PROPERTY_POSSIBLE_STATES] = ACPI_TYPE_STRING, [HP_WMI_PROPERTY_CURRENT_STATE] = ACPI_TYPE_STRING, [HP_WMI_PROPERTY_BASE_UNITS] = ACPI_TYPE_INTEGER, [HP_WMI_PROPERTY_UNIT_MODIFIER] = ACPI_TYPE_INTEGER, [HP_WMI_PROPERTY_CURRENT_READING] = ACPI_TYPE_INTEGER, [HP_WMI_PROPERTY_RATE_UNITS] = ACPI_TYPE_INTEGER, }; enum hp_wmi_platform_events_property { HP_WMI_PLATFORM_EVENTS_PROPERTY_NAME = 0, HP_WMI_PLATFORM_EVENTS_PROPERTY_DESCRIPTION = 1, HP_WMI_PLATFORM_EVENTS_PROPERTY_SOURCE_NAMESPACE = 2, HP_WMI_PLATFORM_EVENTS_PROPERTY_SOURCE_CLASS = 3, HP_WMI_PLATFORM_EVENTS_PROPERTY_CATEGORY = 4, HP_WMI_PLATFORM_EVENTS_PROPERTY_POSSIBLE_SEVERITY = 5, HP_WMI_PLATFORM_EVENTS_PROPERTY_POSSIBLE_STATUS = 6, }; static const acpi_object_type hp_wmi_platform_events_property_map[] = { [HP_WMI_PLATFORM_EVENTS_PROPERTY_NAME] = ACPI_TYPE_STRING, [HP_WMI_PLATFORM_EVENTS_PROPERTY_DESCRIPTION] = ACPI_TYPE_STRING, [HP_WMI_PLATFORM_EVENTS_PROPERTY_SOURCE_NAMESPACE] = ACPI_TYPE_STRING, [HP_WMI_PLATFORM_EVENTS_PROPERTY_SOURCE_CLASS] = ACPI_TYPE_STRING, [HP_WMI_PLATFORM_EVENTS_PROPERTY_CATEGORY] = ACPI_TYPE_INTEGER, [HP_WMI_PLATFORM_EVENTS_PROPERTY_POSSIBLE_SEVERITY] = ACPI_TYPE_INTEGER, [HP_WMI_PLATFORM_EVENTS_PROPERTY_POSSIBLE_STATUS] = ACPI_TYPE_INTEGER, }; enum hp_wmi_event_property { HP_WMI_EVENT_PROPERTY_NAME = 0, HP_WMI_EVENT_PROPERTY_DESCRIPTION = 1, HP_WMI_EVENT_PROPERTY_CATEGORY = 2, HP_WMI_EVENT_PROPERTY_SEVERITY = 3, HP_WMI_EVENT_PROPERTY_STATUS = 4, }; static const acpi_object_type hp_wmi_event_property_map[] = { [HP_WMI_EVENT_PROPERTY_NAME] = ACPI_TYPE_STRING, [HP_WMI_EVENT_PROPERTY_DESCRIPTION] = ACPI_TYPE_STRING, [HP_WMI_EVENT_PROPERTY_CATEGORY] = ACPI_TYPE_INTEGER, [HP_WMI_EVENT_PROPERTY_SEVERITY] = ACPI_TYPE_INTEGER, [HP_WMI_EVENT_PROPERTY_STATUS] = ACPI_TYPE_INTEGER, }; static const enum hwmon_sensor_types hp_wmi_hwmon_type_map[] = { [HP_WMI_TYPE_TEMPERATURE] = hwmon_temp, [HP_WMI_TYPE_VOLTAGE] = hwmon_in, [HP_WMI_TYPE_CURRENT] = hwmon_curr, [HP_WMI_TYPE_AIR_FLOW] = hwmon_fan, }; static const u32 hp_wmi_hwmon_attributes[hwmon_max] = { [hwmon_chip] = HWMON_C_REGISTER_TZ, [hwmon_temp] = HWMON_T_INPUT | HWMON_T_LABEL | HWMON_T_FAULT, [hwmon_in] = HWMON_I_INPUT | HWMON_I_LABEL, [hwmon_curr] = HWMON_C_INPUT | HWMON_C_LABEL, [hwmon_fan] = HWMON_F_INPUT | HWMON_F_LABEL | HWMON_F_FAULT, [hwmon_intrusion] = HWMON_INTRUSION_ALARM, }; /* * struct hp_wmi_numeric_sensor - a HPBIOS_BIOSNumericSensor instance * * Two variants of HPBIOS_BIOSNumericSensor are known. The first is specified * in [1] and appears to be much more widespread. The second was discovered by * decoding BMOF blobs [4], seems to be found only in some newer ZBook systems * [3], and has two new properties and a slightly different property order. * * These differences don't matter on Windows, where WMI object properties are * accessed by name. For us, supporting both variants gets ugly and hacky at * times. The fun begins now; this struct is defined as per the new variant. * * Effective MOF definition: * * #pragma namespace("\\\\.\\root\\HP\\InstrumentedBIOS"); * class HPBIOS_BIOSNumericSensor { * [read] string Name; * [read] string Description; * [read, ValueMap {"0","1","2","3","4","5","6","7","8","9", * "10","11","12"}, Values {"Unknown","Other","Temperature", * "Voltage","Current","Tachometer","Counter","Switch","Lock", * "Humidity","Smoke Detection","Presence","Air Flow"}] * uint32 SensorType; * [read] string OtherSensorType; * [read, ValueMap {"0","1","2","3","4","5","6","7","8","9", * "10","11","12","13","14","15","16","17","18","..", * "0x8000.."}, Values {"Unknown","Other","OK","Degraded", * "Stressed","Predictive Failure","Error", * "Non-Recoverable Error","Starting","Stopping","Stopped", * "In Service","No Contact","Lost Communication","Aborted", * "Dormant","Supporting Entity in Error","Completed", * "Power Mode","DMTF Reserved","Vendor Reserved"}] * uint32 OperationalStatus; * [read] uint32 Size; * [read] string PossibleStates[]; * [read] string CurrentState; * [read, ValueMap {"0","1","2","3","4","5","6","7","8","9", * "10","11","12","13","14","15","16","17","18","19","20", * "21","22","23","24","25","26","27","28","29","30","31", * "32","33","34","35","36","37","38","39","40","41","42", * "43","44","45","46","47","48","49","50","51","52","53", * "54","55","56","57","58","59","60","61","62","63","64", * "65"}, Values {"Unknown","Other","Degrees C","Degrees F", * "Degrees K","Volts","Amps","Watts","Joules","Coulombs", * "VA","Nits","Lumens","Lux","Candelas","kPa","PSI", * "Newtons","CFM","RPM","Hertz","Seconds","Minutes", * "Hours","Days","Weeks","Mils","Inches","Feet", * "Cubic Inches","Cubic Feet","Meters","Cubic Centimeters", * "Cubic Meters","Liters","Fluid Ounces","Radians", * "Steradians","Revolutions","Cycles","Gravities","Ounces", * "Pounds","Foot-Pounds","Ounce-Inches","Gauss","Gilberts", * "Henries","Farads","Ohms","Siemens","Moles","Becquerels", * "PPM (parts/million)","Decibels","DbA","DbC","Grays", * "Sieverts","Color Temperature Degrees K","Bits","Bytes", * "Words (data)","DoubleWords","QuadWords","Percentage"}] * uint32 BaseUnits; * [read] sint32 UnitModifier; * [read] uint32 CurrentReading; * [read] uint32 RateUnits; * }; * * Effective MOF definition of old variant [1] (sans redundant info): * * class HPBIOS_BIOSNumericSensor { * [read] string Name; * [read] string Description; * [read] uint32 SensorType; * [read] string OtherSensorType; * [read] uint32 OperationalStatus; * [read] string CurrentState; * [read] string PossibleStates[]; * [read] uint32 BaseUnits; * [read] sint32 UnitModifier; * [read] uint32 CurrentReading; * }; */ struct hp_wmi_numeric_sensor { const char *name; const char *description; u32 sensor_type; const char *other_sensor_type; /* Explains "Other" SensorType. */ u32 operational_status; u8 size; /* Count of PossibleStates[]. */ const char **possible_states; const char *current_state; u32 base_units; s32 unit_modifier; u32 current_reading; u32 rate_units; }; /* * struct hp_wmi_platform_events - a HPBIOS_PlatformEvents instance * * Instances of this object reveal the set of possible HPBIOS_BIOSEvent * instances for the current system, but it may not always be present. * * Effective MOF definition: * * #pragma namespace("\\\\.\\root\\HP\\InstrumentedBIOS"); * class HPBIOS_PlatformEvents { * [read] string Name; * [read] string Description; * [read] string SourceNamespace; * [read] string SourceClass; * [read, ValueMap {"0","1","2","3","4",".."}, Values { * "Unknown","Configuration Change","Button Pressed", * "Sensor","BIOS Settings","Reserved"}] * uint32 Category; * [read, ValueMap{"0","5","10","15","20","25","30",".."}, * Values{"Unknown","OK","Degraded/Warning","Minor Failure", * "Major Failure","Critical Failure","Non-recoverable Error", * "DMTF Reserved"}] * uint32 PossibleSeverity; * [read, ValueMap {"0","1","2","3","4","5","6","7","8","9", * "10","11","12","13","14","15","16","17","18","..", * "0x8000.."}, Values {"Unknown","Other","OK","Degraded", * "Stressed","Predictive Failure","Error", * "Non-Recoverable Error","Starting","Stopping","Stopped", * "In Service","No Contact","Lost Communication","Aborted", * "Dormant","Supporting Entity in Error","Completed", * "Power Mode","DMTF Reserved","Vendor Reserved"}] * uint32 PossibleStatus; * }; */ struct hp_wmi_platform_events { const char *name; const char *description; const char *source_namespace; const char *source_class; u32 category; u32 possible_severity; u32 possible_status; }; /* * struct hp_wmi_event - a HPBIOS_BIOSEvent instance * * Effective MOF definition [1] (corrected below from original): * * #pragma namespace("\\\\.\\root\\WMI"); * class HPBIOS_BIOSEvent : WMIEvent { * [read] string Name; * [read] string Description; * [read ValueMap {"0","1","2","3","4"}, Values {"Unknown", * "Configuration Change","Button Pressed","Sensor", * "BIOS Settings"}] * uint32 Category; * [read, ValueMap {"0","5","10","15","20","25","30"}, * Values {"Unknown","OK","Degraded/Warning", * "Minor Failure","Major Failure","Critical Failure", * "Non-recoverable Error"}] * uint32 Severity; * [read, ValueMap {"0","1","2","3","4","5","6","7","8", * "9","10","11","12","13","14","15","16","17","18","..", * "0x8000.."}, Values {"Unknown","Other","OK","Degraded", * "Stressed","Predictive Failure","Error", * "Non-Recoverable Error","Starting","Stopping","Stopped", * "In Service","No Contact","Lost Communication","Aborted", * "Dormant","Supporting Entity in Error","Completed", * "Power Mode","DMTF Reserved","Vendor Reserved"}] * uint32 Status; * }; */ struct hp_wmi_event { const char *name; const char *description; u32 category; }; /* * struct hp_wmi_info - sensor info * @nsensor: numeric sensor properties * @instance: its WMI instance number * @state: pointer to driver state * @has_alarm: whether sensor has an alarm flag * @alarm: alarm flag * @type: its hwmon sensor type * @cached_val: current sensor reading value, scaled for hwmon * @last_updated: when these readings were last updated */ struct hp_wmi_info { struct hp_wmi_numeric_sensor nsensor; u8 instance; void *state; /* void *: Avoid forward declaration. */ bool has_alarm; bool alarm; enum hwmon_sensor_types type; long cached_val; unsigned long last_updated; /* In jiffies. */ }; /* * struct hp_wmi_sensors - driver state * @wdev: pointer to the parent WMI device * @info_map: sensor info structs by hwmon type and channel number * @channel_count: count of hwmon channels by hwmon type * @has_intrusion: whether an intrusion sensor is present * @intrusion: intrusion flag * @lock: mutex to lock polling WMI and changes to driver state */ struct hp_wmi_sensors { struct wmi_device *wdev; struct hp_wmi_info **info_map[hwmon_max]; u8 channel_count[hwmon_max]; bool has_intrusion; bool intrusion; struct mutex lock; /* Lock polling WMI and driver state changes. */ }; static bool is_raw_wmi_string(const u8 *pointer, u32 length) { const u16 *ptr; u16 len; /* WMI strings are length-prefixed UTF-16 [5]. */ if (length <= sizeof(*ptr)) return false; length -= sizeof(*ptr); ptr = (const u16 *)pointer; len = *ptr; return len <= length && !(len & 1); } static char *convert_raw_wmi_string(const u8 *buf) { const wchar_t *src; unsigned int cps; unsigned int len; char *dst; int i; src = (const wchar_t *)buf; /* Count UTF-16 code points. Exclude trailing null padding. */ cps = *src / sizeof(*src); while (cps && !src[cps]) cps--; /* Each code point becomes up to 3 UTF-8 characters. */ len = min(cps * 3, HP_WMI_MAX_STR_SIZE - 1); dst = kmalloc((len + 1) * sizeof(*dst), GFP_KERNEL); if (!dst) return NULL; i = utf16s_to_utf8s(++src, cps, UTF16_LITTLE_ENDIAN, dst, len); dst[i] = '\0'; return dst; } /* hp_wmi_strdup - devm_kstrdup, but length-limited */ static char *hp_wmi_strdup(struct device *dev, const char *src) { char *dst; size_t len; len = strnlen(src, HP_WMI_MAX_STR_SIZE - 1); dst = devm_kmalloc(dev, (len + 1) * sizeof(*dst), GFP_KERNEL); if (!dst) return NULL; strscpy(dst, src, len + 1); return dst; } /* hp_wmi_wstrdup - hp_wmi_strdup, but for a raw WMI string */ static char *hp_wmi_wstrdup(struct device *dev, const u8 *buf) { char *src; char *dst; src = convert_raw_wmi_string(buf); if (!src) return NULL; dst = hp_wmi_strdup(dev, strim(src)); /* Note: Copy is trimmed. */ kfree(src); return dst; } /* * hp_wmi_get_wobj - poll WMI for a WMI object instance * @guid: WMI object GUID * @instance: WMI object instance number * * Returns a new WMI object instance on success, or NULL on error. * Caller must kfree() the result. */ static union acpi_object *hp_wmi_get_wobj(const char *guid, u8 instance) { struct acpi_buffer out = { ACPI_ALLOCATE_BUFFER, NULL }; acpi_status err; err = wmi_query_block(guid, instance, &out); if (ACPI_FAILURE(err)) return NULL; return out.pointer; } /* hp_wmi_wobj_instance_count - find count of WMI object instances */ static u8 hp_wmi_wobj_instance_count(const char *guid) { int count; count = wmi_instance_count(guid); return clamp(count, 0, (int)HP_WMI_MAX_INSTANCES); } static int check_wobj(const union acpi_object *wobj, const acpi_object_type property_map[], int last_prop) { acpi_object_type type = wobj->type; acpi_object_type valid_type; union acpi_object *elements; u32 elem_count; int prop; if (type != ACPI_TYPE_PACKAGE) return -EINVAL; elem_count = wobj->package.count; if (elem_count != last_prop + 1) return -EINVAL; elements = wobj->package.elements; for (prop = 0; prop <= last_prop; prop++) { type = elements[prop].type; valid_type = property_map[prop]; if (type != valid_type) { if (type == ACPI_TYPE_BUFFER && valid_type == ACPI_TYPE_STRING && is_raw_wmi_string(elements[prop].buffer.pointer, elements[prop].buffer.length)) continue; return -EINVAL; } } return 0; } static int extract_acpi_value(struct device *dev, union acpi_object *element, acpi_object_type type, u32 *out_value, char **out_string) { switch (type) { case ACPI_TYPE_INTEGER: *out_value = element->integer.value; break; case ACPI_TYPE_STRING: *out_string = element->type == ACPI_TYPE_BUFFER ? hp_wmi_wstrdup(dev, element->buffer.pointer) : hp_wmi_strdup(dev, strim(element->string.pointer)); if (!*out_string) return -ENOMEM; break; default: return -EINVAL; } return 0; } /* * check_numeric_sensor_wobj - validate a HPBIOS_BIOSNumericSensor instance * @wobj: pointer to WMI object instance to check * @out_size: out pointer to count of possible states * @out_is_new: out pointer to whether this is a "new" variant object * * Returns 0 on success, or a negative error code on error. */ static int check_numeric_sensor_wobj(const union acpi_object *wobj, u8 *out_size, bool *out_is_new) { acpi_object_type type = wobj->type; int prop = HP_WMI_PROPERTY_NAME; acpi_object_type valid_type; union acpi_object *elements; u32 elem_count; int last_prop; bool is_new; u8 count; u32 j; u32 i; if (type != ACPI_TYPE_PACKAGE) return -EINVAL; /* * elements is a variable-length array of ACPI objects, one for * each property of the WMI object instance, except that the * strings in PossibleStates[] are flattened into this array * as if each individual string were a property by itself. */ elements = wobj->package.elements; elem_count = wobj->package.count; if (elem_count <= HP_WMI_PROPERTY_SIZE || elem_count > HP_WMI_MAX_PROPERTIES) return -EINVAL; type = elements[HP_WMI_PROPERTY_SIZE].type; switch (type) { case ACPI_TYPE_INTEGER: is_new = true; last_prop = HP_WMI_PROPERTY_RATE_UNITS; break; case ACPI_TYPE_STRING: is_new = false; last_prop = HP_WMI_PROPERTY_CURRENT_READING; break; default: return -EINVAL; } /* * In general, the count of PossibleStates[] must be > 0. * Also, the old variant lacks the Size property, so we may need to * reduce the value of last_prop by 1 when doing arithmetic with it. */ if (elem_count < last_prop - !is_new + 1) return -EINVAL; count = elem_count - (last_prop - !is_new); for (i = 0; i < elem_count && prop <= last_prop; i++, prop++) { type = elements[i].type; valid_type = hp_wmi_property_map[prop]; if (type != valid_type) return -EINVAL; switch (prop) { case HP_WMI_PROPERTY_OPERATIONAL_STATUS: /* Old variant: CurrentState follows OperationalStatus. */ if (!is_new) prop = HP_WMI_PROPERTY_CURRENT_STATE - 1; break; case HP_WMI_PROPERTY_SIZE: /* New variant: Size == count of PossibleStates[]. */ if (count != elements[i].integer.value) return -EINVAL; break; case HP_WMI_PROPERTY_POSSIBLE_STATES: /* PossibleStates[0] has already been type-checked. */ for (j = 0; i + 1 < elem_count && j + 1 < count; j++) { type = elements[++i].type; if (type != valid_type) return -EINVAL; } /* Old variant: BaseUnits follows PossibleStates[]. */ if (!is_new) prop = HP_WMI_PROPERTY_BASE_UNITS - 1; break; case HP_WMI_PROPERTY_CURRENT_STATE: /* Old variant: PossibleStates[] follows CurrentState. */ if (!is_new) prop = HP_WMI_PROPERTY_POSSIBLE_STATES - 1; break; } } if (prop != last_prop + 1) return -EINVAL; *out_size = count; *out_is_new = is_new; return 0; } static int numeric_sensor_is_connected(const struct hp_wmi_numeric_sensor *nsensor) { u32 operational_status = nsensor->operational_status; return operational_status != HP_WMI_STATUS_NO_CONTACT; } static int numeric_sensor_has_fault(const struct hp_wmi_numeric_sensor *nsensor) { u32 operational_status = nsensor->operational_status; switch (operational_status) { case HP_WMI_STATUS_DEGRADED: case HP_WMI_STATUS_STRESSED: /* e.g. Overload, overtemp. */ case HP_WMI_STATUS_PREDICTIVE_FAILURE: /* e.g. Fan removed. */ case HP_WMI_STATUS_ERROR: case HP_WMI_STATUS_NON_RECOVERABLE_ERROR: case HP_WMI_STATUS_NO_CONTACT: case HP_WMI_STATUS_LOST_COMMUNICATION: case HP_WMI_STATUS_ABORTED: case HP_WMI_STATUS_SUPPORTING_ENTITY_IN_ERROR: /* Assume combination by addition; bitwise OR doesn't make sense. */ case HP_WMI_STATUS_COMPLETED + HP_WMI_STATUS_DEGRADED: case HP_WMI_STATUS_COMPLETED + HP_WMI_STATUS_ERROR: return true; } return false; } /* scale_numeric_sensor - scale sensor reading for hwmon */ static long scale_numeric_sensor(const struct hp_wmi_numeric_sensor *nsensor) { u32 current_reading = nsensor->current_reading; s32 unit_modifier = nsensor->unit_modifier; u32 sensor_type = nsensor->sensor_type; u32 base_units = nsensor->base_units; s32 target_modifier; long val; /* Fan readings are in RPM units; others are in milliunits. */ target_modifier = sensor_type == HP_WMI_TYPE_AIR_FLOW ? 0 : -3; val = current_reading; for (; unit_modifier < target_modifier; unit_modifier++) val = DIV_ROUND_CLOSEST(val, 10); for (; unit_modifier > target_modifier; unit_modifier--) { if (val > LONG_MAX / 10) { val = LONG_MAX; break; } val *= 10; } if (sensor_type == HP_WMI_TYPE_TEMPERATURE) { switch (base_units) { case HP_WMI_UNITS_DEGREES_F: val -= MILLI * 32; val = val <= LONG_MAX / 5 ? DIV_ROUND_CLOSEST(val * 5, 9) : DIV_ROUND_CLOSEST(val, 9) * 5; break; case HP_WMI_UNITS_DEGREES_K: val = milli_kelvin_to_millicelsius(val); break; } } return val; } /* * classify_numeric_sensor - classify a numeric sensor * @nsensor: pointer to numeric sensor struct * * Returns an enum hp_wmi_type value on success, * or a negative value if the sensor type is unsupported. */ static int classify_numeric_sensor(const struct hp_wmi_numeric_sensor *nsensor) { u32 sensor_type = nsensor->sensor_type; u32 base_units = nsensor->base_units; const char *name = nsensor->name; switch (sensor_type) { case HP_WMI_TYPE_TEMPERATURE: /* * Some systems have sensors named "X Thermal Index" in "Other" * units. Tested CPU sensor examples were found to be in °C, * albeit perhaps "differently" accurate; e.g. readings were * reliably -6°C vs. coretemp on a HP Compaq Elite 8300, and * +8°C on an EliteOne G1 800. But this is still within the * realm of plausibility for cheaply implemented motherboard * sensors, and chassis readings were about as expected. */ if ((base_units == HP_WMI_UNITS_OTHER && strstr(name, HP_WMI_PATTERN_TEMP_SENSOR)) || base_units == HP_WMI_UNITS_DEGREES_C || base_units == HP_WMI_UNITS_DEGREES_F || base_units == HP_WMI_UNITS_DEGREES_K) return HP_WMI_TYPE_TEMPERATURE; break; case HP_WMI_TYPE_VOLTAGE: if (base_units == HP_WMI_UNITS_VOLTS) return HP_WMI_TYPE_VOLTAGE; break; case HP_WMI_TYPE_CURRENT: if (base_units == HP_WMI_UNITS_AMPS) return HP_WMI_TYPE_CURRENT; break; case HP_WMI_TYPE_AIR_FLOW: /* * Strangely, HP considers fan RPM sensor type to be * "Air Flow" instead of the more intuitive "Tachometer". */ if (base_units == HP_WMI_UNITS_RPM) return HP_WMI_TYPE_AIR_FLOW; break; } return -EINVAL; } static int populate_numeric_sensor_from_wobj(struct device *dev, struct hp_wmi_numeric_sensor *nsensor, union acpi_object *wobj, bool *out_is_new) { int last_prop = HP_WMI_PROPERTY_RATE_UNITS; int prop = HP_WMI_PROPERTY_NAME; const char **possible_states; union acpi_object *element; acpi_object_type type; char *string; bool is_new; u32 value; u8 size; int err; err = check_numeric_sensor_wobj(wobj, &size, &is_new); if (err) return err; possible_states = devm_kcalloc(dev, size, sizeof(*possible_states), GFP_KERNEL); if (!possible_states) return -ENOMEM; element = wobj->package.elements; nsensor->possible_states = possible_states; nsensor->size = size; if (!is_new) last_prop = HP_WMI_PROPERTY_CURRENT_READING; for (; prop <= last_prop; prop++) { type = hp_wmi_property_map[prop]; err = extract_acpi_value(dev, element, type, &value, &string); if (err) return err; element++; switch (prop) { case HP_WMI_PROPERTY_NAME: nsensor->name = string; break; case HP_WMI_PROPERTY_DESCRIPTION: nsensor->description = string; break; case HP_WMI_PROPERTY_SENSOR_TYPE: if (value > HP_WMI_TYPE_AIR_FLOW) return -EINVAL; nsensor->sensor_type = value; break; case HP_WMI_PROPERTY_OTHER_SENSOR_TYPE: nsensor->other_sensor_type = string; break; case HP_WMI_PROPERTY_OPERATIONAL_STATUS: nsensor->operational_status = value; /* Old variant: CurrentState follows OperationalStatus. */ if (!is_new) prop = HP_WMI_PROPERTY_CURRENT_STATE - 1; break; case HP_WMI_PROPERTY_SIZE: break; /* Already set. */ case HP_WMI_PROPERTY_POSSIBLE_STATES: *possible_states++ = string; if (--size) prop--; /* Old variant: BaseUnits follows PossibleStates[]. */ if (!is_new && !size) prop = HP_WMI_PROPERTY_BASE_UNITS - 1; break; case HP_WMI_PROPERTY_CURRENT_STATE: nsensor->current_state = string; /* Old variant: PossibleStates[] follows CurrentState. */ if (!is_new) prop = HP_WMI_PROPERTY_POSSIBLE_STATES - 1; break; case HP_WMI_PROPERTY_BASE_UNITS: nsensor->base_units = value; break; case HP_WMI_PROPERTY_UNIT_MODIFIER: /* UnitModifier is signed. */ nsensor->unit_modifier = (s32)value; break; case HP_WMI_PROPERTY_CURRENT_READING: nsensor->current_reading = value; break; case HP_WMI_PROPERTY_RATE_UNITS: nsensor->rate_units = value; break; default: return -EINVAL; } } *out_is_new = is_new; return 0; } /* update_numeric_sensor_from_wobj - update fungible sensor properties */ static void update_numeric_sensor_from_wobj(struct device *dev, struct hp_wmi_numeric_sensor *nsensor, const union acpi_object *wobj) { const union acpi_object *elements; const union acpi_object *element; const char *new_string; char *trimmed; char *string; bool is_new; int offset; u8 size; int err; err = check_numeric_sensor_wobj(wobj, &size, &is_new); if (err) return; elements = wobj->package.elements; element = &elements[HP_WMI_PROPERTY_OPERATIONAL_STATUS]; nsensor->operational_status = element->integer.value; /* * In general, an index offset is needed after PossibleStates[0]. * On a new variant, CurrentState is after PossibleStates[]. This is * not the case on an old variant, but we still need to offset the * read because CurrentState is where Size would be on a new variant. */ offset = is_new ? size - 1 : -2; element = &elements[HP_WMI_PROPERTY_CURRENT_STATE + offset]; string = element->type == ACPI_TYPE_BUFFER ? convert_raw_wmi_string(element->buffer.pointer) : element->string.pointer; if (string) { trimmed = strim(string); if (strcmp(trimmed, nsensor->current_state)) { new_string = hp_wmi_strdup(dev, trimmed); if (new_string) { devm_kfree(dev, nsensor->current_state); nsensor->current_state = new_string; } } if (element->type == ACPI_TYPE_BUFFER) kfree(string); } /* Old variant: -2 (not -1) because it lacks the Size property. */ if (!is_new) offset = (int)size - 2; /* size is > 0, i.e. may be 1. */ element = &elements[HP_WMI_PROPERTY_UNIT_MODIFIER + offset]; nsensor->unit_modifier = (s32)element->integer.value; element = &elements[HP_WMI_PROPERTY_CURRENT_READING + offset]; nsensor->current_reading = element->integer.value; } /* * check_platform_events_wobj - validate a HPBIOS_PlatformEvents instance * @wobj: pointer to WMI object instance to check * * Returns 0 on success, or a negative error code on error. */ static int check_platform_events_wobj(const union acpi_object *wobj) { return check_wobj(wobj, hp_wmi_platform_events_property_map, HP_WMI_PLATFORM_EVENTS_PROPERTY_POSSIBLE_STATUS); } static int populate_platform_events_from_wobj(struct device *dev, struct hp_wmi_platform_events *pevents, union acpi_object *wobj) { int last_prop = HP_WMI_PLATFORM_EVENTS_PROPERTY_POSSIBLE_STATUS; int prop = HP_WMI_PLATFORM_EVENTS_PROPERTY_NAME; union acpi_object *element; acpi_object_type type; char *string; u32 value; int err; err = check_platform_events_wobj(wobj); if (err) return err; element = wobj->package.elements; for (; prop <= last_prop; prop++, element++) { type = hp_wmi_platform_events_property_map[prop]; err = extract_acpi_value(dev, element, type, &value, &string); if (err) return err; switch (prop) { case HP_WMI_PLATFORM_EVENTS_PROPERTY_NAME: pevents->name = string; break; case HP_WMI_PLATFORM_EVENTS_PROPERTY_DESCRIPTION: pevents->description = string; break; case HP_WMI_PLATFORM_EVENTS_PROPERTY_SOURCE_NAMESPACE: if (strcasecmp(HP_WMI_EVENT_NAMESPACE, string)) return -EINVAL; pevents->source_namespace = string; break; case HP_WMI_PLATFORM_EVENTS_PROPERTY_SOURCE_CLASS: if (strcasecmp(HP_WMI_EVENT_CLASS, string)) return -EINVAL; pevents->source_class = string; break; case HP_WMI_PLATFORM_EVENTS_PROPERTY_CATEGORY: pevents->category = value; break; case HP_WMI_PLATFORM_EVENTS_PROPERTY_POSSIBLE_SEVERITY: pevents->possible_severity = value; break; case HP_WMI_PLATFORM_EVENTS_PROPERTY_POSSIBLE_STATUS: pevents->possible_status = value; break; default: return -EINVAL; } } return 0; } /* * check_event_wobj - validate a HPBIOS_BIOSEvent instance * @wobj: pointer to WMI object instance to check * * Returns 0 on success, or a negative error code on error. */ static int check_event_wobj(const union acpi_object *wobj) { return check_wobj(wobj, hp_wmi_event_property_map, HP_WMI_EVENT_PROPERTY_STATUS); } static int populate_event_from_wobj(struct device *dev, struct hp_wmi_event *event, union acpi_object *wobj) { int prop = HP_WMI_EVENT_PROPERTY_NAME; union acpi_object *element; acpi_object_type type; char *string; u32 value; int err; err = check_event_wobj(wobj); if (err) return err; element = wobj->package.elements; for (; prop <= HP_WMI_EVENT_PROPERTY_CATEGORY; prop++, element++) { type = hp_wmi_event_property_map[prop]; err = extract_acpi_value(dev, element, type, &value, &string); if (err) return err; switch (prop) { case HP_WMI_EVENT_PROPERTY_NAME: event->name = string; break; case HP_WMI_EVENT_PROPERTY_DESCRIPTION: event->description = string; break; case HP_WMI_EVENT_PROPERTY_CATEGORY: event->category = value; break; default: return -EINVAL; } } return 0; } /* * classify_event - classify an event * @name: event name * @category: event category * * Classify instances of both HPBIOS_PlatformEvents and HPBIOS_BIOSEvent from * property values. Recognition criteria are based on multiple ACPI dumps [3]. * * Returns an enum hp_wmi_type value on success, * or a negative value if the event type is unsupported. */ static int classify_event(const char *event_name, u32 category) { if (category != HP_WMI_CATEGORY_SENSOR) return -EINVAL; /* Fan events have Name "X Stall". */ if (strstr(event_name, HP_WMI_PATTERN_FAN_ALARM)) return HP_WMI_TYPE_AIR_FLOW; /* Intrusion events have Name "Hood Intrusion". */ if (!strcmp(event_name, HP_WMI_PATTERN_INTRUSION_ALARM)) return HP_WMI_TYPE_INTRUSION; /* * Temperature events have Name either "Thermal Caution" or * "Thermal Critical". Deal only with "Thermal Critical" events. * * "Thermal Caution" events have Status "Stressed", informing us that * the OperationalStatus of the related sensor has become "Stressed". * However, this is already a fault condition that will clear itself * when the sensor recovers, so we have no further interest in them. */ if (!strcmp(event_name, HP_WMI_PATTERN_TEMP_ALARM)) return HP_WMI_TYPE_TEMPERATURE; return -EINVAL; } /* * interpret_info - interpret sensor for hwmon * @info: pointer to sensor info struct * * Should be called after the numeric sensor member has been updated. */ static void interpret_info(struct hp_wmi_info *info) { const struct hp_wmi_numeric_sensor *nsensor = &info->nsensor; info->cached_val = scale_numeric_sensor(nsensor); info->last_updated = jiffies; } /* * hp_wmi_update_info - poll WMI to update sensor info * @state: pointer to driver state * @info: pointer to sensor info struct * * Returns 0 on success, or a negative error code on error. */ static int hp_wmi_update_info(struct hp_wmi_sensors *state, struct hp_wmi_info *info) { struct hp_wmi_numeric_sensor *nsensor = &info->nsensor; struct device *dev = &state->wdev->dev; const union acpi_object *wobj; u8 instance = info->instance; int ret = 0; if (time_after(jiffies, info->last_updated + HZ)) { mutex_lock(&state->lock); wobj = hp_wmi_get_wobj(HP_WMI_NUMERIC_SENSOR_GUID, instance); if (!wobj) { ret = -EIO; goto out_unlock; } update_numeric_sensor_from_wobj(dev, nsensor, wobj); interpret_info(info); kfree(wobj); out_unlock: mutex_unlock(&state->lock); } return ret; } static int basic_string_show(struct seq_file *seqf, void *ignored) { const char *str = seqf->private; seq_printf(seqf, "%s\n", str); return 0; } DEFINE_SHOW_ATTRIBUTE(basic_string); static int fungible_show(struct seq_file *seqf, enum hp_wmi_property prop) { struct hp_wmi_numeric_sensor *nsensor; struct hp_wmi_sensors *state; struct hp_wmi_info *info; int err; info = seqf->private; state = info->state; nsensor = &info->nsensor; err = hp_wmi_update_info(state, info); if (err) return err; switch (prop) { case HP_WMI_PROPERTY_OPERATIONAL_STATUS: seq_printf(seqf, "%u\n", nsensor->operational_status); break; case HP_WMI_PROPERTY_CURRENT_STATE: seq_printf(seqf, "%s\n", nsensor->current_state); break; case HP_WMI_PROPERTY_UNIT_MODIFIER: seq_printf(seqf, "%d\n", nsensor->unit_modifier); break; case HP_WMI_PROPERTY_CURRENT_READING: seq_printf(seqf, "%u\n", nsensor->current_reading); break; default: return -EOPNOTSUPP; } return 0; } static int operational_status_show(struct seq_file *seqf, void *ignored) { return fungible_show(seqf, HP_WMI_PROPERTY_OPERATIONAL_STATUS); } DEFINE_SHOW_ATTRIBUTE(operational_status); static int current_state_show(struct seq_file *seqf, void *ignored) { return fungible_show(seqf, HP_WMI_PROPERTY_CURRENT_STATE); } DEFINE_SHOW_ATTRIBUTE(current_state); static int possible_states_show(struct seq_file *seqf, void *ignored) { struct hp_wmi_numeric_sensor *nsensor = seqf->private; u8 i; for (i = 0; i < nsensor->size; i++) seq_printf(seqf, "%s%s", i ? "," : "", nsensor->possible_states[i]); seq_puts(seqf, "\n"); return 0; } DEFINE_SHOW_ATTRIBUTE(possible_states); static int unit_modifier_show(struct seq_file *seqf, void *ignored) { return fungible_show(seqf, HP_WMI_PROPERTY_UNIT_MODIFIER); } DEFINE_SHOW_ATTRIBUTE(unit_modifier); static int current_reading_show(struct seq_file *seqf, void *ignored) { return fungible_show(seqf, HP_WMI_PROPERTY_CURRENT_READING); } DEFINE_SHOW_ATTRIBUTE(current_reading); /* hp_wmi_devm_debugfs_remove - devm callback for debugfs cleanup */ static void hp_wmi_devm_debugfs_remove(void *res) { debugfs_remove_recursive(res); } /* hp_wmi_debugfs_init - create and populate debugfs directory tree */ static void hp_wmi_debugfs_init(struct device *dev, struct hp_wmi_info *info, struct hp_wmi_platform_events *pevents, u8 icount, u8 pcount, bool is_new) { struct hp_wmi_numeric_sensor *nsensor; char buf[HP_WMI_MAX_STR_SIZE]; struct dentry *debugfs; struct dentry *entries; struct dentry *dir; int err; u8 i; /* dev_name() gives a not-very-friendly GUID for WMI devices. */ scnprintf(buf, sizeof(buf), "hp-wmi-sensors-%u", dev->id); debugfs = debugfs_create_dir(buf, NULL); if (IS_ERR(debugfs)) return; err = devm_add_action_or_reset(dev, hp_wmi_devm_debugfs_remove, debugfs); if (err) return; entries = debugfs_create_dir("sensor", debugfs); for (i = 0; i < icount; i++, info++) { nsensor = &info->nsensor; scnprintf(buf, sizeof(buf), "%u", i); dir = debugfs_create_dir(buf, entries); debugfs_create_file("name", 0444, dir, (void *)nsensor->name, &basic_string_fops); debugfs_create_file("description", 0444, dir, (void *)nsensor->description, &basic_string_fops); debugfs_create_u32("sensor_type", 0444, dir, &nsensor->sensor_type); debugfs_create_file("other_sensor_type", 0444, dir, (void *)nsensor->other_sensor_type, &basic_string_fops); debugfs_create_file("operational_status", 0444, dir, info, &operational_status_fops); debugfs_create_file("possible_states", 0444, dir, nsensor, &possible_states_fops); debugfs_create_file("current_state", 0444, dir, info, ¤t_state_fops); debugfs_create_u32("base_units", 0444, dir, &nsensor->base_units); debugfs_create_file("unit_modifier", 0444, dir, info, &unit_modifier_fops); debugfs_create_file("current_reading", 0444, dir, info, ¤t_reading_fops); if (is_new) debugfs_create_u32("rate_units", 0444, dir, &nsensor->rate_units); } if (!pcount) return; entries = debugfs_create_dir("platform_events", debugfs); for (i = 0; i < pcount; i++, pevents++) { scnprintf(buf, sizeof(buf), "%u", i); dir = debugfs_create_dir(buf, entries); debugfs_create_file("name", 0444, dir, (void *)pevents->name, &basic_string_fops); debugfs_create_file("description", 0444, dir, (void *)pevents->description, &basic_string_fops); debugfs_create_file("source_namespace", 0444, dir, (void *)pevents->source_namespace, &basic_string_fops); debugfs_create_file("source_class", 0444, dir, (void *)pevents->source_class, &basic_string_fops); debugfs_create_u32("category", 0444, dir, &pevents->category); debugfs_create_u32("possible_severity", 0444, dir, &pevents->possible_severity); debugfs_create_u32("possible_status", 0444, dir, &pevents->possible_status); } } static umode_t hp_wmi_hwmon_is_visible(const void *drvdata, enum hwmon_sensor_types type, u32 attr, int channel) { const struct hp_wmi_sensors *state = drvdata; const struct hp_wmi_info *info; if (type == hwmon_intrusion) return state->has_intrusion ? 0644 : 0; if (!state->info_map[type] || !state->info_map[type][channel]) return 0; info = state->info_map[type][channel]; if ((type == hwmon_temp && attr == hwmon_temp_alarm) || (type == hwmon_fan && attr == hwmon_fan_alarm)) return info->has_alarm ? 0444 : 0; return 0444; } static int hp_wmi_hwmon_read(struct device *dev, enum hwmon_sensor_types type, u32 attr, int channel, long *out_val) { struct hp_wmi_sensors *state = dev_get_drvdata(dev); const struct hp_wmi_numeric_sensor *nsensor; struct hp_wmi_info *info; int err; if (type == hwmon_intrusion) { *out_val = state->intrusion ? 1 : 0; return 0; } info = state->info_map[type][channel]; if ((type == hwmon_temp && attr == hwmon_temp_alarm) || (type == hwmon_fan && attr == hwmon_fan_alarm)) { *out_val = info->alarm ? 1 : 0; info->alarm = false; return 0; } nsensor = &info->nsensor; err = hp_wmi_update_info(state, info); if (err) return err; if ((type == hwmon_temp && attr == hwmon_temp_fault) || (type == hwmon_fan && attr == hwmon_fan_fault)) *out_val = numeric_sensor_has_fault(nsensor); else *out_val = info->cached_val; return 0; } static int hp_wmi_hwmon_read_string(struct device *dev, enum hwmon_sensor_types type, u32 attr, int channel, const char **out_str) { const struct hp_wmi_sensors *state = dev_get_drvdata(dev); const struct hp_wmi_info *info; info = state->info_map[type][channel]; *out_str = info->nsensor.name; return 0; } static int hp_wmi_hwmon_write(struct device *dev, enum hwmon_sensor_types type, u32 attr, int channel, long val) { struct hp_wmi_sensors *state = dev_get_drvdata(dev); if (val) return -EINVAL; mutex_lock(&state->lock); state->intrusion = false; mutex_unlock(&state->lock); return 0; } static const struct hwmon_ops hp_wmi_hwmon_ops = { .is_visible = hp_wmi_hwmon_is_visible, .read = hp_wmi_hwmon_read, .read_string = hp_wmi_hwmon_read_string, .write = hp_wmi_hwmon_write, }; static struct hwmon_chip_info hp_wmi_chip_info = { .ops = &hp_wmi_hwmon_ops, .info = NULL, }; static struct hp_wmi_info *match_fan_event(struct hp_wmi_sensors *state, const char *event_description) { struct hp_wmi_info **ptr_info = state->info_map[hwmon_fan]; u8 fan_count = state->channel_count[hwmon_fan]; struct hp_wmi_info *info; const char *name; u8 i; /* Fan event has Description "X Speed". Sensor has Name "X[ Speed]". */ for (i = 0; i < fan_count; i++, ptr_info++) { info = *ptr_info; name = info->nsensor.name; if (strstr(event_description, name)) return info; } return NULL; } static u8 match_temp_events(struct hp_wmi_sensors *state, const char *event_description, struct hp_wmi_info *temp_info[]) { struct hp_wmi_info **ptr_info = state->info_map[hwmon_temp]; u8 temp_count = state->channel_count[hwmon_temp]; struct hp_wmi_info *info; const char *name; u8 count = 0; bool is_cpu; bool is_sys; u8 i; /* Description is either "CPU Thermal Index" or "Chassis Thermal Index". */ is_cpu = !strcmp(event_description, HP_WMI_PATTERN_CPU_TEMP); is_sys = !strcmp(event_description, HP_WMI_PATTERN_SYS_TEMP); if (!is_cpu && !is_sys) return 0; /* * CPU event: Match one sensor with Name either "CPU Thermal Index" or * "CPU Temperature", or multiple with Name(s) "CPU[#] Temperature". * * Chassis event: Match one sensor with Name either * "Chassis Thermal Index" or "System Ambient Temperature". */ for (i = 0; i < temp_count; i++, ptr_info++) { info = *ptr_info; name = info->nsensor.name; if ((is_cpu && (!strcmp(name, HP_WMI_PATTERN_CPU_TEMP) || !strcmp(name, HP_WMI_PATTERN_CPU_TEMP2))) || (is_sys && (!strcmp(name, HP_WMI_PATTERN_SYS_TEMP) || !strcmp(name, HP_WMI_PATTERN_SYS_TEMP2)))) { temp_info[0] = info; return 1; } if (is_cpu && (strstr(name, HP_WMI_PATTERN_CPU) && strstr(name, HP_WMI_PATTERN_TEMP))) temp_info[count++] = info; } return count; } /* hp_wmi_devm_debugfs_remove - devm callback for WMI event handler removal */ static void hp_wmi_devm_notify_remove(void *ignored) { wmi_remove_notify_handler(HP_WMI_EVENT_GUID); } /* hp_wmi_notify - WMI event notification handler */ static void hp_wmi_notify(u32 value, void *context) { struct hp_wmi_info *temp_info[HP_WMI_MAX_INSTANCES] = {}; struct acpi_buffer out = { ACPI_ALLOCATE_BUFFER, NULL }; struct hp_wmi_sensors *state = context; struct device *dev = &state->wdev->dev; struct hp_wmi_event event = {}; struct hp_wmi_info *fan_info; union acpi_object *wobj; acpi_status err; int event_type; u8 count; /* * The following warning may occur in the kernel log: * * ACPI Warning: \_SB.WMID._WED: Return type mismatch - * found Package, expected Integer/String/Buffer * * After using [4] to decode BMOF blobs found in [3], careless copying * of BIOS code seems the most likely explanation for this warning. * HP_WMI_EVENT_GUID refers to \\.\root\WMI\HPBIOS_BIOSEvent on * business-class systems, but it refers to \\.\root\WMI\hpqBEvnt on * non-business-class systems. Per the existing hp-wmi driver, it * looks like an instance of hpqBEvnt delivered as event data may * indeed take the form of a raw ACPI_BUFFER on non-business-class * systems ("may" because ASL shows some BIOSes do strange things). * * In any case, we can ignore this warning, because we always validate * the event data to ensure it is an ACPI_PACKAGE containing a * HPBIOS_BIOSEvent instance. */ mutex_lock(&state->lock); err = wmi_get_event_data(value, &out); if (ACPI_FAILURE(err)) goto out_unlock; wobj = out.pointer; if (!wobj) goto out_unlock; err = populate_event_from_wobj(dev, &event, wobj); if (err) { dev_warn(dev, "Bad event data (ACPI type %d)\n", wobj->type); goto out_free_wobj; } event_type = classify_event(event.name, event.category); switch (event_type) { case HP_WMI_TYPE_AIR_FLOW: fan_info = match_fan_event(state, event.description); if (fan_info) fan_info->alarm = true; break; case HP_WMI_TYPE_INTRUSION: state->intrusion = true; break; case HP_WMI_TYPE_TEMPERATURE: count = match_temp_events(state, event.description, temp_info); while (count) temp_info[--count]->alarm = true; break; default: break; } out_free_wobj: kfree(wobj); devm_kfree(dev, event.name); devm_kfree(dev, event.description); out_unlock: mutex_unlock(&state->lock); } static int init_platform_events(struct device *dev, struct hp_wmi_platform_events **out_pevents, u8 *out_pcount) { struct hp_wmi_platform_events *pevents_arr; struct hp_wmi_platform_events *pevents; union acpi_object *wobj; u8 count; int err; u8 i; count = hp_wmi_wobj_instance_count(HP_WMI_PLATFORM_EVENTS_GUID); if (!count) { *out_pcount = 0; dev_dbg(dev, "No platform events\n"); return 0; } pevents_arr = devm_kcalloc(dev, count, sizeof(*pevents), GFP_KERNEL); if (!pevents_arr) return -ENOMEM; for (i = 0, pevents = pevents_arr; i < count; i++, pevents++) { wobj = hp_wmi_get_wobj(HP_WMI_PLATFORM_EVENTS_GUID, i); if (!wobj) return -EIO; err = populate_platform_events_from_wobj(dev, pevents, wobj); kfree(wobj); if (err) return err; } *out_pevents = pevents_arr; *out_pcount = count; dev_dbg(dev, "Found %u platform events\n", count); return 0; } static int init_numeric_sensors(struct hp_wmi_sensors *state, struct hp_wmi_info *connected[], struct hp_wmi_info **out_info, u8 *out_icount, u8 *out_count, bool *out_is_new) { struct hp_wmi_info ***info_map = state->info_map; u8 *channel_count = state->channel_count; struct device *dev = &state->wdev->dev; struct hp_wmi_numeric_sensor *nsensor; u8 channel_index[hwmon_max] = {}; enum hwmon_sensor_types type; struct hp_wmi_info *info_arr; struct hp_wmi_info *info; union acpi_object *wobj; u8 count = 0; bool is_new; u8 icount; int wtype; int err; u8 c; u8 i; icount = hp_wmi_wobj_instance_count(HP_WMI_NUMERIC_SENSOR_GUID); if (!icount) return -ENODATA; info_arr = devm_kcalloc(dev, icount, sizeof(*info), GFP_KERNEL); if (!info_arr) return -ENOMEM; for (i = 0, info = info_arr; i < icount; i++, info++) { wobj = hp_wmi_get_wobj(HP_WMI_NUMERIC_SENSOR_GUID, i); if (!wobj) return -EIO; info->instance = i; info->state = state; nsensor = &info->nsensor; err = populate_numeric_sensor_from_wobj(dev, nsensor, wobj, &is_new); kfree(wobj); if (err) return err; if (!numeric_sensor_is_connected(nsensor)) continue; wtype = classify_numeric_sensor(nsensor); if (wtype < 0) continue; type = hp_wmi_hwmon_type_map[wtype]; channel_count[type]++; info->type = type; interpret_info(info); connected[count++] = info; } dev_dbg(dev, "Found %u sensors (%u connected)\n", i, count); for (i = 0; i < count; i++) { info = connected[i]; type = info->type; c = channel_index[type]++; if (!info_map[type]) { info_map[type] = devm_kcalloc(dev, channel_count[type], sizeof(*info_map), GFP_KERNEL); if (!info_map[type]) return -ENOMEM; } info_map[type][c] = info; } *out_info = info_arr; *out_icount = icount; *out_count = count; *out_is_new = is_new; return 0; } static bool find_event_attributes(struct hp_wmi_sensors *state, struct hp_wmi_platform_events *pevents, u8 pevents_count) { /* * The existence of this HPBIOS_PlatformEvents instance: * * { * Name = "Rear Chassis Fan0 Stall"; * Description = "Rear Chassis Fan0 Speed"; * Category = 3; // "Sensor" * PossibleSeverity = 25; // "Critical Failure" * PossibleStatus = 5; // "Predictive Failure" * [...] * } * * means that this HPBIOS_BIOSEvent instance may occur: * * { * Name = "Rear Chassis Fan0 Stall"; * Description = "Rear Chassis Fan0 Speed"; * Category = 3; // "Sensor" * Severity = 25; // "Critical Failure" * Status = 5; // "Predictive Failure" * } * * After the event occurs (e.g. because the fan was unplugged), * polling the related HPBIOS_BIOSNumericSensor instance gives: * * { * Name = "Rear Chassis Fan0"; * Description = "Reports rear chassis fan0 speed"; * OperationalStatus = 5; // "Predictive Failure", was 3 ("OK") * CurrentReading = 0; * [...] * } * * In this example, the hwmon fan channel for "Rear Chassis Fan0" * should support the alarm flag and have it be set if the related * HPBIOS_BIOSEvent instance occurs. * * In addition to fan events, temperature (CPU/chassis) and intrusion * events are relevant to hwmon [2]. Note that much information in [2] * is unreliable; it is referenced in addition to ACPI dumps [3] merely * to support the conclusion that sensor and event names/descriptions * are systematic enough to allow this driver to match them. * * Complications and limitations: * * - Strings are freeform and may vary, cf. sensor Name "CPU0 Fan" * on a Z420 vs. "CPU Fan Speed" on an EliteOne 800 G1. * - Leading/trailing whitespace is a rare but real possibility [3]. * - The HPBIOS_PlatformEvents object may not exist or its instances * may show that the system only has e.g. BIOS setting-related * events (cf. the ProBook 4540s and ProBook 470 G0 [3]). */ struct hp_wmi_info *temp_info[HP_WMI_MAX_INSTANCES] = {}; const char *event_description; struct hp_wmi_info *fan_info; bool has_events = false; const char *event_name; u32 event_category; int event_type; u8 count; u8 i; for (i = 0; i < pevents_count; i++, pevents++) { event_name = pevents->name; event_description = pevents->description; event_category = pevents->category; event_type = classify_event(event_name, event_category); switch (event_type) { case HP_WMI_TYPE_AIR_FLOW: fan_info = match_fan_event(state, event_description); if (!fan_info) break; fan_info->has_alarm = true; has_events = true; break; case HP_WMI_TYPE_INTRUSION: state->has_intrusion = true; has_events = true; break; case HP_WMI_TYPE_TEMPERATURE: count = match_temp_events(state, event_description, temp_info); if (!count) break; while (count) temp_info[--count]->has_alarm = true; has_events = true; break; default: break; } } return has_events; } static int make_chip_info(struct hp_wmi_sensors *state, bool has_events) { const struct hwmon_channel_info **ptr_channel_info; struct hp_wmi_info ***info_map = state->info_map; u8 *channel_count = state->channel_count; struct hwmon_channel_info *channel_info; struct device *dev = &state->wdev->dev; enum hwmon_sensor_types type; u8 type_count = 0; u32 *config; u32 attr; u8 count; u8 i; if (channel_count[hwmon_temp]) channel_count[hwmon_chip] = 1; if (has_events && state->has_intrusion) channel_count[hwmon_intrusion] = 1; for (type = hwmon_chip; type < hwmon_max; type++) if (channel_count[type]) type_count++; channel_info = devm_kcalloc(dev, type_count, sizeof(*channel_info), GFP_KERNEL); if (!channel_info) return -ENOMEM; ptr_channel_info = devm_kcalloc(dev, type_count + 1, sizeof(*ptr_channel_info), GFP_KERNEL); if (!ptr_channel_info) return -ENOMEM; hp_wmi_chip_info.info = ptr_channel_info; for (type = hwmon_chip; type < hwmon_max; type++) { count = channel_count[type]; if (!count) continue; config = devm_kcalloc(dev, count + 1, sizeof(*config), GFP_KERNEL); if (!config) return -ENOMEM; attr = hp_wmi_hwmon_attributes[type]; channel_info->type = type; channel_info->config = config; memset32(config, attr, count); *ptr_channel_info++ = channel_info++; if (!has_events || (type != hwmon_temp && type != hwmon_fan)) continue; attr = type == hwmon_temp ? HWMON_T_ALARM : HWMON_F_ALARM; for (i = 0; i < count; i++) if (info_map[type][i]->has_alarm) config[i] |= attr; } return 0; } static bool add_event_handler(struct hp_wmi_sensors *state) { struct device *dev = &state->wdev->dev; int err; err = wmi_install_notify_handler(HP_WMI_EVENT_GUID, hp_wmi_notify, state); if (err) { dev_info(dev, "Failed to subscribe to WMI event\n"); return false; } err = devm_add_action_or_reset(dev, hp_wmi_devm_notify_remove, NULL); if (err) return false; return true; } static int hp_wmi_sensors_init(struct hp_wmi_sensors *state) { struct hp_wmi_info *connected[HP_WMI_MAX_INSTANCES]; struct hp_wmi_platform_events *pevents = NULL; struct device *dev = &state->wdev->dev; struct hp_wmi_info *info; struct device *hwdev; bool has_events; bool is_new; u8 icount; u8 pcount; u8 count; int err; err = init_platform_events(dev, &pevents, &pcount); if (err) return err; err = init_numeric_sensors(state, connected, &info, &icount, &count, &is_new); if (err) return err; if (IS_ENABLED(CONFIG_DEBUG_FS)) hp_wmi_debugfs_init(dev, info, pevents, icount, pcount, is_new); if (!count) return 0; /* No connected sensors; debugfs only. */ has_events = find_event_attributes(state, pevents, pcount); /* Survive failure to install WMI event handler. */ if (has_events && !add_event_handler(state)) has_events = false; err = make_chip_info(state, has_events); if (err) return err; hwdev = devm_hwmon_device_register_with_info(dev, "hp_wmi_sensors", state, &hp_wmi_chip_info, NULL); return PTR_ERR_OR_ZERO(hwdev); } static int hp_wmi_sensors_probe(struct wmi_device *wdev, const void *context) { struct device *dev = &wdev->dev; struct hp_wmi_sensors *state; state = devm_kzalloc(dev, sizeof(*state), GFP_KERNEL); if (!state) return -ENOMEM; state->wdev = wdev; mutex_init(&state->lock); dev_set_drvdata(dev, state); return hp_wmi_sensors_init(state); } static const struct wmi_device_id hp_wmi_sensors_id_table[] = { { HP_WMI_NUMERIC_SENSOR_GUID, NULL }, {}, }; static struct wmi_driver hp_wmi_sensors_driver = { .driver = { .name = "hp-wmi-sensors" }, .id_table = hp_wmi_sensors_id_table, .probe = hp_wmi_sensors_probe, }; module_wmi_driver(hp_wmi_sensors_driver); MODULE_AUTHOR("James Seo <james@equiv.tech>"); MODULE_DESCRIPTION("HP WMI Sensors driver"); MODULE_LICENSE("GPL");
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