/* SPDX-License-Identifier: GPL-2.0-only */ /* * SCMI Message Protocol driver header * * Copyright (C) 2018-2021 ARM Ltd. */ #ifndef _LINUX_SCMI_PROTOCOL_H #define _LINUX_SCMI_PROTOCOL_H #include <linux/bitfield.h> #include <linux/device.h> #include <linux/notifier.h> #include <linux/types.h> #define SCMI_MAX_STR_SIZE 64 #define SCMI_SHORT_NAME_MAX_SIZE 16 #define SCMI_MAX_NUM_RATES 16 /** * struct scmi_revision_info - version information structure * * @major_ver: Major ABI version. Change here implies risk of backward * compatibility break. * @minor_ver: Minor ABI version. Change here implies new feature addition, * or compatible change in ABI. * @num_protocols: Number of protocols that are implemented, excluding the * base protocol. * @num_agents: Number of agents in the system. * @impl_ver: A vendor-specific implementation version. * @vendor_id: A vendor identifier(Null terminated ASCII string) * @sub_vendor_id: A sub-vendor identifier(Null terminated ASCII string) */ struct scmi_revision_info { u16 major_ver; u16 minor_ver; u8 num_protocols; u8 num_agents; u32 impl_ver; char vendor_id[SCMI_SHORT_NAME_MAX_SIZE]; char sub_vendor_id[SCMI_SHORT_NAME_MAX_SIZE]; }; struct scmi_clock_info { char name[SCMI_MAX_STR_SIZE]; unsigned int enable_latency; bool rate_discrete; bool rate_changed_notifications; bool rate_change_requested_notifications; union { struct { int num_rates; u64 rates[SCMI_MAX_NUM_RATES]; } list; struct { u64 min_rate; u64 max_rate; u64 step_size; } range; }; }; struct scmi_handle; struct scmi_device; struct scmi_protocol_handle; /** * struct scmi_clk_proto_ops - represents the various operations provided * by SCMI Clock Protocol * * @count_get: get the count of clocks provided by SCMI * @info_get: get the information of the specified clock * @rate_get: request the current clock rate of a clock * @rate_set: set the clock rate of a clock * @enable: enables the specified clock * @disable: disables the specified clock */ struct scmi_clk_proto_ops { int (*count_get)(const struct scmi_protocol_handle *ph); const struct scmi_clock_info *(*info_get) (const struct scmi_protocol_handle *ph, u32 clk_id); int (*rate_get)(const struct scmi_protocol_handle *ph, u32 clk_id, u64 *rate); int (*rate_set)(const struct scmi_protocol_handle *ph, u32 clk_id, u64 rate); int (*enable)(const struct scmi_protocol_handle *ph, u32 clk_id); int (*disable)(const struct scmi_protocol_handle *ph, u32 clk_id); int (*enable_atomic)(const struct scmi_protocol_handle *ph, u32 clk_id); int (*disable_atomic)(const struct scmi_protocol_handle *ph, u32 clk_id); }; /** * struct scmi_perf_proto_ops - represents the various operations provided * by SCMI Performance Protocol * * @limits_set: sets limits on the performance level of a domain * @limits_get: gets limits on the performance level of a domain * @level_set: sets the performance level of a domain * @level_get: gets the performance level of a domain * @device_domain_id: gets the scmi domain id for a given device * @transition_latency_get: gets the DVFS transition latency for a given device * @device_opps_add: adds all the OPPs for a given device * @freq_set: sets the frequency for a given device using sustained frequency * to sustained performance level mapping * @freq_get: gets the frequency for a given device using sustained frequency * to sustained performance level mapping * @est_power_get: gets the estimated power cost for a given performance domain * at a given frequency * @fast_switch_possible: indicates if fast DVFS switching is possible or not * for a given device * @power_scale_mw_get: indicates if the power values provided are in milliWatts * or in some other (abstract) scale */ struct scmi_perf_proto_ops { int (*limits_set)(const struct scmi_protocol_handle *ph, u32 domain, u32 max_perf, u32 min_perf); int (*limits_get)(const struct scmi_protocol_handle *ph, u32 domain, u32 *max_perf, u32 *min_perf); int (*level_set)(const struct scmi_protocol_handle *ph, u32 domain, u32 level, bool poll); int (*level_get)(const struct scmi_protocol_handle *ph, u32 domain, u32 *level, bool poll); int (*device_domain_id)(struct device *dev); int (*transition_latency_get)(const struct scmi_protocol_handle *ph, struct device *dev); int (*device_opps_add)(const struct scmi_protocol_handle *ph, struct device *dev); int (*freq_set)(const struct scmi_protocol_handle *ph, u32 domain, unsigned long rate, bool poll); int (*freq_get)(const struct scmi_protocol_handle *ph, u32 domain, unsigned long *rate, bool poll); int (*est_power_get)(const struct scmi_protocol_handle *ph, u32 domain, unsigned long *rate, unsigned long *power); bool (*fast_switch_possible)(const struct scmi_protocol_handle *ph, struct device *dev); bool (*power_scale_mw_get)(const struct scmi_protocol_handle *ph); }; /** * struct scmi_power_proto_ops - represents the various operations provided * by SCMI Power Protocol * * @num_domains_get: get the count of power domains provided by SCMI * @name_get: gets the name of a power domain * @state_set: sets the power state of a power domain * @state_get: gets the power state of a power domain */ struct scmi_power_proto_ops { int (*num_domains_get)(const struct scmi_protocol_handle *ph); const char *(*name_get)(const struct scmi_protocol_handle *ph, u32 domain); #define SCMI_POWER_STATE_TYPE_SHIFT 30 #define SCMI_POWER_STATE_ID_MASK (BIT(28) - 1) #define SCMI_POWER_STATE_PARAM(type, id) \ ((((type) & BIT(0)) << SCMI_POWER_STATE_TYPE_SHIFT) | \ ((id) & SCMI_POWER_STATE_ID_MASK)) #define SCMI_POWER_STATE_GENERIC_ON SCMI_POWER_STATE_PARAM(0, 0) #define SCMI_POWER_STATE_GENERIC_OFF SCMI_POWER_STATE_PARAM(1, 0) int (*state_set)(const struct scmi_protocol_handle *ph, u32 domain, u32 state); int (*state_get)(const struct scmi_protocol_handle *ph, u32 domain, u32 *state); }; /** * struct scmi_sensor_reading - represent a timestamped read * * Used by @reading_get_timestamped method. * * @value: The signed value sensor read. * @timestamp: An unsigned timestamp for the sensor read, as provided by * SCMI platform. Set to zero when not available. */ struct scmi_sensor_reading { long long value; unsigned long long timestamp; }; /** * struct scmi_range_attrs - specifies a sensor or axis values' range * @min_range: The minimum value which can be represented by the sensor/axis. * @max_range: The maximum value which can be represented by the sensor/axis. */ struct scmi_range_attrs { long long min_range; long long max_range; }; /** * struct scmi_sensor_axis_info - describes one sensor axes * @id: The axes ID. * @type: Axes type. Chosen amongst one of @enum scmi_sensor_class. * @scale: Power-of-10 multiplier applied to the axis unit. * @name: NULL-terminated string representing axes name as advertised by * SCMI platform. * @extended_attrs: Flag to indicate the presence of additional extended * attributes for this axes. * @resolution: Extended attribute representing the resolution of the axes. * Set to 0 if not reported by this axes. * @exponent: Extended attribute representing the power-of-10 multiplier that * is applied to the resolution field. Set to 0 if not reported by * this axes. * @attrs: Extended attributes representing minimum and maximum values * measurable by this axes. Set to 0 if not reported by this sensor. */ struct scmi_sensor_axis_info { unsigned int id; unsigned int type; int scale; char name[SCMI_MAX_STR_SIZE]; bool extended_attrs; unsigned int resolution; int exponent; struct scmi_range_attrs attrs; }; /** * struct scmi_sensor_intervals_info - describes number and type of available * update intervals * @segmented: Flag for segmented intervals' representation. When True there * will be exactly 3 intervals in @desc, with each entry * representing a member of a segment in this order: * {lowest update interval, highest update interval, step size} * @count: Number of intervals described in @desc. * @desc: Array of @count interval descriptor bitmask represented as detailed in * the SCMI specification: it can be accessed using the accompanying * macros. * @prealloc_pool: A minimal preallocated pool of desc entries used to avoid * lesser-than-64-bytes dynamic allocation for small @count * values. */ struct scmi_sensor_intervals_info { bool segmented; unsigned int count; #define SCMI_SENS_INTVL_SEGMENT_LOW 0 #define SCMI_SENS_INTVL_SEGMENT_HIGH 1 #define SCMI_SENS_INTVL_SEGMENT_STEP 2 unsigned int *desc; #define SCMI_SENS_INTVL_GET_SECS(x) FIELD_GET(GENMASK(20, 5), (x)) #define SCMI_SENS_INTVL_GET_EXP(x) \ ({ \ int __signed_exp = FIELD_GET(GENMASK(4, 0), (x)); \ \ if (__signed_exp & BIT(4)) \ __signed_exp |= GENMASK(31, 5); \ __signed_exp; \ }) #define SCMI_MAX_PREALLOC_POOL 16 unsigned int prealloc_pool[SCMI_MAX_PREALLOC_POOL]; }; /** * struct scmi_sensor_info - represents information related to one of the * available sensors. * @id: Sensor ID. * @type: Sensor type. Chosen amongst one of @enum scmi_sensor_class. * @scale: Power-of-10 multiplier applied to the sensor unit. * @num_trip_points: Number of maximum configurable trip points. * @async: Flag for asynchronous read support. * @update: Flag for continuouos update notification support. * @timestamped: Flag for timestamped read support. * @tstamp_scale: Power-of-10 multiplier applied to the sensor timestamps to * represent it in seconds. * @num_axis: Number of supported axis if any. Reported as 0 for scalar sensors. * @axis: Pointer to an array of @num_axis descriptors. * @intervals: Descriptor of available update intervals. * @sensor_config: A bitmask reporting the current sensor configuration as * detailed in the SCMI specification: it can accessed and * modified through the accompanying macros. * @name: NULL-terminated string representing sensor name as advertised by * SCMI platform. * @extended_scalar_attrs: Flag to indicate the presence of additional extended * attributes for this sensor. * @sensor_power: Extended attribute representing the average power * consumed by the sensor in microwatts (uW) when it is active. * Reported here only for scalar sensors. * Set to 0 if not reported by this sensor. * @resolution: Extended attribute representing the resolution of the sensor. * Reported here only for scalar sensors. * Set to 0 if not reported by this sensor. * @exponent: Extended attribute representing the power-of-10 multiplier that is * applied to the resolution field. * Reported here only for scalar sensors. * Set to 0 if not reported by this sensor. * @scalar_attrs: Extended attributes representing minimum and maximum * measurable values by this sensor. * Reported here only for scalar sensors. * Set to 0 if not reported by this sensor. */ struct scmi_sensor_info { unsigned int id; unsigned int type; int scale; unsigned int num_trip_points; bool async; bool update; bool timestamped; int tstamp_scale; unsigned int num_axis; struct scmi_sensor_axis_info *axis; struct scmi_sensor_intervals_info intervals; unsigned int sensor_config; #define SCMI_SENS_CFG_UPDATE_SECS_MASK GENMASK(31, 16) #define SCMI_SENS_CFG_GET_UPDATE_SECS(x) \ FIELD_GET(SCMI_SENS_CFG_UPDATE_SECS_MASK, (x)) #define SCMI_SENS_CFG_UPDATE_EXP_MASK GENMASK(15, 11) #define SCMI_SENS_CFG_GET_UPDATE_EXP(x) \ ({ \ int __signed_exp = \ FIELD_GET(SCMI_SENS_CFG_UPDATE_EXP_MASK, (x)); \ \ if (__signed_exp & BIT(4)) \ __signed_exp |= GENMASK(31, 5); \ __signed_exp; \ }) #define SCMI_SENS_CFG_ROUND_MASK GENMASK(10, 9) #define SCMI_SENS_CFG_ROUND_AUTO 2 #define SCMI_SENS_CFG_ROUND_UP 1 #define SCMI_SENS_CFG_ROUND_DOWN 0 #define SCMI_SENS_CFG_TSTAMP_ENABLED_MASK BIT(1) #define SCMI_SENS_CFG_TSTAMP_ENABLE 1 #define SCMI_SENS_CFG_TSTAMP_DISABLE 0 #define SCMI_SENS_CFG_IS_TSTAMP_ENABLED(x) \ FIELD_GET(SCMI_SENS_CFG_TSTAMP_ENABLED_MASK, (x)) #define SCMI_SENS_CFG_SENSOR_ENABLED_MASK BIT(0) #define SCMI_SENS_CFG_SENSOR_ENABLE 1 #define SCMI_SENS_CFG_SENSOR_DISABLE 0 char name[SCMI_MAX_STR_SIZE]; #define SCMI_SENS_CFG_IS_ENABLED(x) FIELD_GET(BIT(0), (x)) bool extended_scalar_attrs; unsigned int sensor_power; unsigned int resolution; int exponent; struct scmi_range_attrs scalar_attrs; }; /* * Partial list from Distributed Management Task Force (DMTF) specification: * DSP0249 (Platform Level Data Model specification) */ enum scmi_sensor_class { NONE = 0x0, UNSPEC = 0x1, TEMPERATURE_C = 0x2, TEMPERATURE_F = 0x3, TEMPERATURE_K = 0x4, VOLTAGE = 0x5, CURRENT = 0x6, POWER = 0x7, ENERGY = 0x8, CHARGE = 0x9, VOLTAMPERE = 0xA, NITS = 0xB, LUMENS = 0xC, LUX = 0xD, CANDELAS = 0xE, KPA = 0xF, PSI = 0x10, NEWTON = 0x11, CFM = 0x12, RPM = 0x13, HERTZ = 0x14, SECS = 0x15, MINS = 0x16, HOURS = 0x17, DAYS = 0x18, WEEKS = 0x19, MILS = 0x1A, INCHES = 0x1B, FEET = 0x1C, CUBIC_INCHES = 0x1D, CUBIC_FEET = 0x1E, METERS = 0x1F, CUBIC_CM = 0x20, CUBIC_METERS = 0x21, LITERS = 0x22, FLUID_OUNCES = 0x23, RADIANS = 0x24, STERADIANS = 0x25, REVOLUTIONS = 0x26, CYCLES = 0x27, GRAVITIES = 0x28, OUNCES = 0x29, POUNDS = 0x2A, FOOT_POUNDS = 0x2B, OUNCE_INCHES = 0x2C, GAUSS = 0x2D, GILBERTS = 0x2E, HENRIES = 0x2F, FARADS = 0x30, OHMS = 0x31, SIEMENS = 0x32, MOLES = 0x33, BECQUERELS = 0x34, PPM = 0x35, DECIBELS = 0x36, DBA = 0x37, DBC = 0x38, GRAYS = 0x39, SIEVERTS = 0x3A, COLOR_TEMP_K = 0x3B, BITS = 0x3C, BYTES = 0x3D, WORDS = 0x3E, DWORDS = 0x3F, QWORDS = 0x40, PERCENTAGE = 0x41, PASCALS = 0x42, COUNTS = 0x43, GRAMS = 0x44, NEWTON_METERS = 0x45, HITS = 0x46, MISSES = 0x47, RETRIES = 0x48, OVERRUNS = 0x49, UNDERRUNS = 0x4A, COLLISIONS = 0x4B, PACKETS = 0x4C, MESSAGES = 0x4D, CHARS = 0x4E, ERRORS = 0x4F, CORRECTED_ERRS = 0x50, UNCORRECTABLE_ERRS = 0x51, SQ_MILS = 0x52, SQ_INCHES = 0x53, SQ_FEET = 0x54, SQ_CM = 0x55, SQ_METERS = 0x56, RADIANS_SEC = 0x57, BPM = 0x58, METERS_SEC_SQUARED = 0x59, METERS_SEC = 0x5A, CUBIC_METERS_SEC = 0x5B, MM_MERCURY = 0x5C, RADIANS_SEC_SQUARED = 0x5D, OEM_UNIT = 0xFF }; /** * struct scmi_sensor_proto_ops - represents the various operations provided * by SCMI Sensor Protocol * * @count_get: get the count of sensors provided by SCMI * @info_get: get the information of the specified sensor * @trip_point_config: selects and configures a trip-point of interest * @reading_get: gets the current value of the sensor * @reading_get_timestamped: gets the current value and timestamp, when * available, of the sensor. (as of v3.0 spec) * Supports multi-axis sensors for sensors which * supports it and if the @reading array size of * @count entry equals the sensor num_axis * @config_get: Get sensor current configuration * @config_set: Set sensor current configuration */ struct scmi_sensor_proto_ops { int (*count_get)(const struct scmi_protocol_handle *ph); const struct scmi_sensor_info *(*info_get) (const struct scmi_protocol_handle *ph, u32 sensor_id); int (*trip_point_config)(const struct scmi_protocol_handle *ph, u32 sensor_id, u8 trip_id, u64 trip_value); int (*reading_get)(const struct scmi_protocol_handle *ph, u32 sensor_id, u64 *value); int (*reading_get_timestamped)(const struct scmi_protocol_handle *ph, u32 sensor_id, u8 count, struct scmi_sensor_reading *readings); int (*config_get)(const struct scmi_protocol_handle *ph, u32 sensor_id, u32 *sensor_config); int (*config_set)(const struct scmi_protocol_handle *ph, u32 sensor_id, u32 sensor_config); }; /** * struct scmi_reset_proto_ops - represents the various operations provided * by SCMI Reset Protocol * * @num_domains_get: get the count of reset domains provided by SCMI * @name_get: gets the name of a reset domain * @latency_get: gets the reset latency for the specified reset domain * @reset: resets the specified reset domain * @assert: explicitly assert reset signal of the specified reset domain * @deassert: explicitly deassert reset signal of the specified reset domain */ struct scmi_reset_proto_ops { int (*num_domains_get)(const struct scmi_protocol_handle *ph); const char *(*name_get)(const struct scmi_protocol_handle *ph, u32 domain); int (*latency_get)(const struct scmi_protocol_handle *ph, u32 domain); int (*reset)(const struct scmi_protocol_handle *ph, u32 domain); int (*assert)(const struct scmi_protocol_handle *ph, u32 domain); int (*deassert)(const struct scmi_protocol_handle *ph, u32 domain); }; enum scmi_voltage_level_mode { SCMI_VOLTAGE_LEVEL_SET_AUTO, SCMI_VOLTAGE_LEVEL_SET_SYNC, }; /** * struct scmi_voltage_info - describe one available SCMI Voltage Domain * * @id: the domain ID as advertised by the platform * @segmented: defines the layout of the entries of array @levels_uv. * - when True the entries are to be interpreted as triplets, * each defining a segment representing a range of equally * space voltages: <lowest_volts>, <highest_volt>, <step_uV> * - when False the entries simply represent a single discrete * supported voltage level * @negative_volts_allowed: True if any of the entries of @levels_uv represent * a negative voltage. * @async_level_set: True when the voltage domain supports asynchronous level * set commands. * @name: name assigned to the Voltage Domain by platform * @num_levels: number of total entries in @levels_uv. * @levels_uv: array of entries describing the available voltage levels for * this domain. */ struct scmi_voltage_info { unsigned int id; bool segmented; bool negative_volts_allowed; bool async_level_set; char name[SCMI_MAX_STR_SIZE]; unsigned int num_levels; #define SCMI_VOLTAGE_SEGMENT_LOW 0 #define SCMI_VOLTAGE_SEGMENT_HIGH 1 #define SCMI_VOLTAGE_SEGMENT_STEP 2 int *levels_uv; }; /** * struct scmi_voltage_proto_ops - represents the various operations provided * by SCMI Voltage Protocol * * @num_domains_get: get the count of voltage domains provided by SCMI * @info_get: get the information of the specified domain * @config_set: set the config for the specified domain * @config_get: get the config of the specified domain * @level_set: set the voltage level for the specified domain * @level_get: get the voltage level of the specified domain */ struct scmi_voltage_proto_ops { int (*num_domains_get)(const struct scmi_protocol_handle *ph); const struct scmi_voltage_info __must_check *(*info_get) (const struct scmi_protocol_handle *ph, u32 domain_id); int (*config_set)(const struct scmi_protocol_handle *ph, u32 domain_id, u32 config); #define SCMI_VOLTAGE_ARCH_STATE_OFF 0x0 #define SCMI_VOLTAGE_ARCH_STATE_ON 0x7 int (*config_get)(const struct scmi_protocol_handle *ph, u32 domain_id, u32 *config); int (*level_set)(const struct scmi_protocol_handle *ph, u32 domain_id, enum scmi_voltage_level_mode mode, s32 volt_uV); int (*level_get)(const struct scmi_protocol_handle *ph, u32 domain_id, s32 *volt_uV); }; /** * struct scmi_notify_ops - represents notifications' operations provided by * SCMI core * @devm_event_notifier_register: Managed registration of a notifier_block for * the requested event * @devm_event_notifier_unregister: Managed unregistration of a notifier_block * for the requested event * @event_notifier_register: Register a notifier_block for the requested event * @event_notifier_unregister: Unregister a notifier_block for the requested * event * * A user can register/unregister its own notifier_block against the wanted * platform instance regarding the desired event identified by the * tuple: (proto_id, evt_id, src_id) using the provided register/unregister * interface where: * * @sdev: The scmi_device to use when calling the devres managed ops devm_ * @handle: The handle identifying the platform instance to use, when not * calling the managed ops devm_ * @proto_id: The protocol ID as in SCMI Specification * @evt_id: The message ID of the desired event as in SCMI Specification * @src_id: A pointer to the desired source ID if different sources are * possible for the protocol (like domain_id, sensor_id...etc) * * @src_id can be provided as NULL if it simply does NOT make sense for * the protocol at hand, OR if the user is explicitly interested in * receiving notifications from ANY existent source associated to the * specified proto_id / evt_id. * * Received notifications are finally delivered to the registered users, * invoking the callback provided with the notifier_block *nb as follows: * * int user_cb(nb, evt_id, report) * * with: * * @nb: The notifier block provided by the user * @evt_id: The message ID of the delivered event * @report: A custom struct describing the specific event delivered */ struct scmi_notify_ops { int (*devm_event_notifier_register)(struct scmi_device *sdev, u8 proto_id, u8 evt_id, const u32 *src_id, struct notifier_block *nb); int (*devm_event_notifier_unregister)(struct scmi_device *sdev, u8 proto_id, u8 evt_id, const u32 *src_id, struct notifier_block *nb); int (*event_notifier_register)(const struct scmi_handle *handle, u8 proto_id, u8 evt_id, const u32 *src_id, struct notifier_block *nb); int (*event_notifier_unregister)(const struct scmi_handle *handle, u8 proto_id, u8 evt_id, const u32 *src_id, struct notifier_block *nb); }; /** * struct scmi_handle - Handle returned to ARM SCMI clients for usage. * * @dev: pointer to the SCMI device * @version: pointer to the structure containing SCMI version information * @devm_protocol_get: devres managed method to acquire a protocol and get specific * operations and a dedicated protocol handler * @devm_protocol_put: devres managed method to release a protocol * @is_transport_atomic: method to check if the underlying transport for this * instance handle is configured to support atomic * transactions for commands. * Some users of the SCMI stack in the upper layers could * be interested to know if they can assume SCMI * command transactions associated to this handle will * never sleep and act accordingly. * An optional atomic threshold value could be returned * where configured. * @notify_ops: pointer to set of notifications related operations */ struct scmi_handle { struct device *dev; struct scmi_revision_info *version; const void __must_check * (*devm_protocol_get)(struct scmi_device *sdev, u8 proto, struct scmi_protocol_handle **ph); void (*devm_protocol_put)(struct scmi_device *sdev, u8 proto); bool (*is_transport_atomic)(const struct scmi_handle *handle, unsigned int *atomic_threshold); const struct scmi_notify_ops *notify_ops; }; enum scmi_std_protocol { SCMI_PROTOCOL_BASE = 0x10, SCMI_PROTOCOL_POWER = 0x11, SCMI_PROTOCOL_SYSTEM = 0x12, SCMI_PROTOCOL_PERF = 0x13, SCMI_PROTOCOL_CLOCK = 0x14, SCMI_PROTOCOL_SENSOR = 0x15, SCMI_PROTOCOL_RESET = 0x16, SCMI_PROTOCOL_VOLTAGE = 0x17, }; enum scmi_system_events { SCMI_SYSTEM_SHUTDOWN, SCMI_SYSTEM_COLDRESET, SCMI_SYSTEM_WARMRESET, SCMI_SYSTEM_POWERUP, SCMI_SYSTEM_SUSPEND, SCMI_SYSTEM_MAX }; struct scmi_device { u32 id; u8 protocol_id; const char *name; struct device dev; struct scmi_handle *handle; }; #define to_scmi_dev(d) container_of(d, struct scmi_device, dev) struct scmi_device * scmi_device_create(struct device_node *np, struct device *parent, int protocol, const char *name); void scmi_device_destroy(struct scmi_device *scmi_dev); struct scmi_device_id { u8 protocol_id; const char *name; }; struct scmi_driver { const char *name; int (*probe)(struct scmi_device *sdev); void (*remove)(struct scmi_device *sdev); const struct scmi_device_id *id_table; struct device_driver driver; }; #define to_scmi_driver(d) container_of(d, struct scmi_driver, driver) #if IS_REACHABLE(CONFIG_ARM_SCMI_PROTOCOL) int scmi_driver_register(struct scmi_driver *driver, struct module *owner, const char *mod_name); void scmi_driver_unregister(struct scmi_driver *driver); #else static inline int scmi_driver_register(struct scmi_driver *driver, struct module *owner, const char *mod_name) { return -EINVAL; } static inline void scmi_driver_unregister(struct scmi_driver *driver) {} #endif /* CONFIG_ARM_SCMI_PROTOCOL */ #define scmi_register(driver) \ scmi_driver_register(driver, THIS_MODULE, KBUILD_MODNAME) #define scmi_unregister(driver) \ scmi_driver_unregister(driver) /** * module_scmi_driver() - Helper macro for registering a scmi driver * @__scmi_driver: scmi_driver structure * * Helper macro for scmi drivers to set up proper module init / exit * functions. Replaces module_init() and module_exit() and keeps people from * printing pointless things to the kernel log when their driver is loaded. */ #define module_scmi_driver(__scmi_driver) \ module_driver(__scmi_driver, scmi_register, scmi_unregister) /** * module_scmi_protocol() - Helper macro for registering a scmi protocol * @__scmi_protocol: scmi_protocol structure * * Helper macro for scmi drivers to set up proper module init / exit * functions. Replaces module_init() and module_exit() and keeps people from * printing pointless things to the kernel log when their driver is loaded. */ #define module_scmi_protocol(__scmi_protocol) \ module_driver(__scmi_protocol, \ scmi_protocol_register, scmi_protocol_unregister) struct scmi_protocol; int scmi_protocol_register(const struct scmi_protocol *proto); void scmi_protocol_unregister(const struct scmi_protocol *proto); /* SCMI Notification API - Custom Event Reports */ enum scmi_notification_events { SCMI_EVENT_POWER_STATE_CHANGED = 0x0, SCMI_EVENT_CLOCK_RATE_CHANGED = 0x0, SCMI_EVENT_CLOCK_RATE_CHANGE_REQUESTED = 0x1, SCMI_EVENT_PERFORMANCE_LIMITS_CHANGED = 0x0, SCMI_EVENT_PERFORMANCE_LEVEL_CHANGED = 0x1, SCMI_EVENT_SENSOR_TRIP_POINT_EVENT = 0x0, SCMI_EVENT_SENSOR_UPDATE = 0x1, SCMI_EVENT_RESET_ISSUED = 0x0, SCMI_EVENT_BASE_ERROR_EVENT = 0x0, SCMI_EVENT_SYSTEM_POWER_STATE_NOTIFIER = 0x0, }; struct scmi_power_state_changed_report { ktime_t timestamp; unsigned int agent_id; unsigned int domain_id; unsigned int power_state; }; struct scmi_clock_rate_notif_report { ktime_t timestamp; unsigned int agent_id; unsigned int clock_id; unsigned long long rate; }; struct scmi_system_power_state_notifier_report { ktime_t timestamp; unsigned int agent_id; unsigned int flags; unsigned int system_state; }; struct scmi_perf_limits_report { ktime_t timestamp; unsigned int agent_id; unsigned int domain_id; unsigned int range_max; unsigned int range_min; }; struct scmi_perf_level_report { ktime_t timestamp; unsigned int agent_id; unsigned int domain_id; unsigned int performance_level; }; struct scmi_sensor_trip_point_report { ktime_t timestamp; unsigned int agent_id; unsigned int sensor_id; unsigned int trip_point_desc; }; struct scmi_sensor_update_report { ktime_t timestamp; unsigned int agent_id; unsigned int sensor_id; unsigned int readings_count; struct scmi_sensor_reading readings[]; }; struct scmi_reset_issued_report { ktime_t timestamp; unsigned int agent_id; unsigned int domain_id; unsigned int reset_state; }; struct scmi_base_error_report { ktime_t timestamp; unsigned int agent_id; bool fatal; unsigned int cmd_count; unsigned long long reports[]; }; #endif /* _LINUX_SCMI_PROTOCOL_H */