/* Copyright (c) 2013, The Linux Foundation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 and * only version 2 as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #ifndef _LINUX_BIF_CONSUMER_H_ #define _LINUX_BIF_CONSUMER_H_ #include #include #include #define BIF_DEVICE_ID_BYTE_LENGTH 8 #define BIF_UNIQUE_ID_BYTE_LENGTH 10 #define BIF_UNIQUE_ID_BIT_LENGTH 80 #define BIF_PRIMARY_SLAVE_DEV_ADR 0x01 /** * enum bif_transaction - BIF master bus transaction types * %BIF_TRANS_WD: Write data * %BIF_TRANS_ERA: Extended register address * %BIF_TRANS_WRA: Write register address * %BIF_TRANS_RRA: Read register address * %BIF_TRANS_BC: Bus command * %BIF_TRANS_EDA: Extended device address * %BIF_TRANS_SDA: Slave device address * * These values correspond to BIF word bits: BCF, bit 9, bit 8. * BCF_n bit is inserted automatically. */ enum bif_transaction { BIF_TRANS_WD = 0x00, BIF_TRANS_ERA = 0x01, BIF_TRANS_WRA = 0x02, BIF_TRANS_RRA = 0x03, BIF_TRANS_BC = 0x04, BIF_TRANS_EDA = 0x05, BIF_TRANS_SDA = 0x06, }; /* BIF slave response components */ #define BIF_SLAVE_RD_ACK 0x200 #define BIF_SLAVE_RD_EOT 0x100 #define BIF_SLAVE_RD_DATA 0x0FF #define BIF_SLAVE_RD_ERR 0x0FF #define BIF_SLAVE_TACK_ACK 0x200 #define BIF_SLAVE_TACK_WCNT 0x0FF #define BIF_SLAVE_TACK_ERR 0x0FF /** * enum bif_bus_command - MIPI defined bus commands to use in BC transaction * %BIF_CMD_BRES: Bus reset of all slaves * %BIF_CMD_PDWN: Put all slaves into power down mode * %BIF_CMD_STBY: Put all slaves into standby mode * %BIF_CMD_EINT: Enable interrupts for all slaves * %BIF_CMD_ISTS: Poll interrupt status for all slaves. Expects BQ * response if any slave has a pending interrupt. * %BIF_CMD_RBL: Specify the burst read length for the next read * transaction. Bits 3 to 0 should also be ORed on in * order to specify the number of bytes to read. * %BIF_CMD_RBE: Specify the extended burst read length for the next read * transaction. Bits 3 to 0 should also be ORed on in * order to specify the number of bytes to read. The burst * read length for RBEy and RBLx = 16 * y + x. * %BIF_CMD_DASM: Device activation stick mode. This keeps a slave * selected if it would otherwise become unselected by the * next transaction. * %BIF_CMD_DISS: UID search start * %BIF_CMD_DILC: UID length check. Expects BQ response if all 80 UID * bits for a given slave have been entered. * %BIF_CMD_DIE0: UID search enter 0 * %BIF_CMD_DIE1: UID search enter 1 * %BIF_CMD_DIP0: UID search probe 0 * %BIF_CMD_DIP1: UID search probe 1 * %BIF_CMD_DRES: Device reset of selected slaves * %BIF_CMD_TQ: Transaction query; expects TACK response * %BIF_CMD_AIO: Address increment off for the next transaction * * These values correspond to BIF word bits 7 to 0. */ enum bif_bus_command { BIF_CMD_BRES = 0x00, BIF_CMD_PDWN = 0x02, BIF_CMD_STBY = 0x03, BIF_CMD_EINT = 0x10, BIF_CMD_ISTS = 0x11, BIF_CMD_RBL = 0x20, BIF_CMD_RBE = 0x30, BIF_CMD_DASM = 0x40, BIF_CMD_DISS = 0x80, BIF_CMD_DILC = 0x81, BIF_CMD_DIE0 = 0x84, BIF_CMD_DIE1 = 0x85, BIF_CMD_DIP0 = 0x86, BIF_CMD_DIP1 = 0x87, BIF_CMD_DRES = 0xC0, BIF_CMD_TQ = 0xC2, BIF_CMD_AIO = 0xC4, }; /** * struct bif_ddb_l1_data - MIPI defined L1 DDB data structure * @revision: DDB version; should be 0x10 for DDB v1.0 * @level: DDB level support; should be 0x03 for DDB L1 and L2 * @device_class: MIPI device class; should be 0x0800 * @manufacturer_id: Manufacturer ID number allocated by MIPI * @product_id: Manufacturer specified product ID number * @length: Size of L2 function directory in bytes */ struct bif_ddb_l1_data { u8 revision; u8 level; u16 device_class; u16 manufacturer_id; u16 product_id; u16 length; }; /** * struct bif_ddb_l2_data - MIPI defined L2 DDB function data structure * @function_type: Defines the type of the function. The type may be * either MIPI or manufacturer defined. * @function_version: Defines the version of the function. The version may * be either MIPI or manufacturer defined. * @function_pointer: Address in BIF slave memory where the register map for * the function begins. */ struct bif_ddb_l2_data { u8 function_type; u8 function_version; u16 function_pointer; }; /** * enum bif_mipi_function_type - MIPI defined DDB L2 function types * %BIF_FUNC_PROTOCOL: Protocol function which provides access to core * BIF communication features. * %BIF_FUNC_SLAVE_CONTROL: Slave control function which provides control * for BIF slave interrupts and tasks. * %BIF_FUNC_TEMPERATURE: Temperature sensor function which provides a * means to accurately read the battery temperature * in a single-shot or periodic fashion. * %BIF_FUNC_NVM: Non-volatile memory function which provides a * means to store data onto a BIF slave that is * non-volatile. Secondary slave objects are also * found through the NVM function. * %BIF_FUNC_AUTHENTICATION: Authentication function which provides a means * to authenticate batteries. This function does * not have a MIPI defined implimentation. Instead * all aspects of the authentication function are * left to the discretion of the manufacturer. */ enum bif_mipi_function_type { BIF_FUNC_PROTOCOL = 0x01, BIF_FUNC_SLAVE_CONTROL = 0x02, BIF_FUNC_TEMPERATURE = 0x03, BIF_FUNC_NVM = 0x04, BIF_FUNC_AUTHENTICATION = 0x05, }; #define BIF_DDB_L1_BASE_ADDR 0x0000 #define BIF_DDB_L2_BASE_ADDR 0x000A /** * enum bif_slave_error_code - MIPI defined BIF slave error codes * %BIF_ERR_NONE: No error occurred * %BIF_ERR_GENERAL: An unenumerated error occurred * %BIF_ERR_PARITY: A Hamming-15 parity check failed for a word * sent on the bus * %BIF_ERR_INVERSION: More than 8 bits in a word were 1 * %BIF_ERR_BAD_LENGTH: Word had more or less than 17 bits * %BIF_ERR_TIMING: Bit timing was violated in a word * %BIF_ERR_UNKNOWN_CMD: Bus command was unknown to the slave * %BIF_ERR_CMD_SEQ: Commands with ordering dependency were not * sent in the right order * %BIF_ERR_BUS_COLLISION: BCL was already low at the beginning of a new * transaction * %BIF_ERR_SLAVE_BUSY: Slave is busy and cannot respond * %BIF_ERR_FATAL: Slave is in an unrecoverable error state and * must be reset * * These values are present in the ERR portion of an RD or TACK slave response * word. These values can also be found in the ERR_CODE register of the * protocol function. */ enum bif_slave_error_code { BIF_ERR_NONE = 0x00, BIF_ERR_GENERAL = 0x10, BIF_ERR_PARITY = 0x11, BIF_ERR_INVERSION = 0x12, BIF_ERR_BAD_LENGTH = 0x13, BIF_ERR_TIMING = 0x14, BIF_ERR_UNKNOWN_CMD = 0x15, BIF_ERR_CMD_SEQ = 0x16, BIF_ERR_BUS_COLLISION = 0x1F, BIF_ERR_SLAVE_BUSY = 0x20, BIF_ERR_FATAL = 0x7F, }; /** * struct bif_protocol_function - constant data present in protocol function * @l2_entry: Pointer to protocol function L2 DDB data struct * @protocol_pointer: BIF slave address where protocol registers begin * @device_id_pointer: BIF slave address where device ID begins * @device_id: The 8-byte unique device ID in MSB to LSB order */ struct bif_protocol_function { struct bif_ddb_l2_data *l2_entry; u16 protocol_pointer; u16 device_id_pointer; u8 device_id[BIF_DEVICE_ID_BYTE_LENGTH]; /* Unique ID */ }; #define PROTOCOL_FUNC_DEV_ADR_ADDR(protocol_pointer) ((protocol_pointer) + 0) #define PROTOCOL_FUNC_ERR_CODE_ADDR(protocol_pointer) ((protocol_pointer) + 2) #define PROTOCOL_FUNC_ERR_CNT_ADDR(protocol_pointer) ((protocol_pointer) + 3) #define PROTOCOL_FUNC_WORD_CNT_ADDR(protocol_pointer) ((protocol_pointer) + 4) /** * struct bif_slave_control_function - constant data present in slave control * function as well internal software state parameters * @l2_entry: Pointer to slave control function L2 DDB data struct * @slave_ctrl_pointer: BIF slave address where slave control registers begin * @task_count: Number of tasks supported by the slave * @irq_notifier_list: List of notifiers for consumers drivers that wish to be * notified when any given interrupt triggers. This list * is dynamically allocated with length task_count. */ struct bif_slave_control_function { struct bif_ddb_l2_data *l2_entry; u16 slave_ctrl_pointer; unsigned int task_count; struct blocking_notifier_head *irq_notifier_list; }; #define SLAVE_CTRL_TASKS_PER_SET 8 /** * bif_slave_control_task_is_valid() - returns true if the specified task * is supported by the slave or false if it isn't * @func: Pointer to slave's slave control function structure * @task: Slave task number to check */ static inline bool bif_slave_control_task_is_valid(struct bif_slave_control_function *func, unsigned int task) { return func ? task < func->task_count : false; } #define SLAVE_CTRL_FUNC_IRQ_EN_ADDR(slave_ctrl_pointer, task) \ ((slave_ctrl_pointer) + 4 * ((task) / SLAVE_CTRL_TASKS_PER_SET) + 0) #define SLAVE_CTRL_FUNC_IRQ_STATUS_ADDR(slave_ctrl_pointer, task) \ ((slave_ctrl_pointer) + 4 * ((task) / SLAVE_CTRL_TASKS_PER_SET) + 1) #define SLAVE_CTRL_FUNC_IRQ_CLEAR_ADDR(slave_ctrl_pointer, task) \ SLAVE_CTRL_FUNC_IRQ_STATUS_ADDR(slave_ctrl_pointer, task) #define SLAVE_CTRL_FUNC_TASK_TRIGGER_ADDR(slave_ctrl_pointer, task) \ ((slave_ctrl_pointer) + 4 * ((task) / SLAVE_CTRL_TASKS_PER_SET) + 2) #define SLAVE_CTRL_FUNC_TASK_BUSY_ADDR(slave_ctrl_pointer, task) \ SLAVE_CTRL_FUNC_TASK_TRIGGER_ADDR(slave_ctrl_pointer, task) #define SLAVE_CTRL_FUNC_TASK_AUTO_TRIGGER_ADDR(slave_ctrl_pointer, task) \ ((slave_ctrl_pointer) + 4 * ((task) / SLAVE_CTRL_TASKS_PER_SET) + 3) /** * struct bif_temperature_function - constant data present in temperature * sensor function * @temperatuer_pointer: BIF slave address where temperature sensor * control registers begin * @slave_control_channel: Slave control channel associated with the * temperature sensor function. This channel is * also the task number. * @accuracy_pointer: BIF slave address where temperature accuracy * registers begin */ struct bif_temperature_function { u16 temperature_pointer; u8 slave_control_channel; u16 accuracy_pointer; }; /** * enum bif_mipi_object_type - MIPI defined BIF object types * %BIF_OBJ_END_OF_LIST: Indicates that the end of the object list in * NVM has been reached * %BIF_OBJ_SEC_SLAVE: Specifies the UIDs of secondary slaves found * inside of the battery pack * %BIF_OBJ_BATT_PARAM: Specifies some variety of battery parameter. * There is no MIPI defined format for this object * type so parsing is manufacturer specific. */ enum bif_mipi_object_type { BIF_OBJ_END_OF_LIST = 0x00, BIF_OBJ_SEC_SLAVE = 0x01, BIF_OBJ_BATT_PARAM = 0x02, }; /** * struct bif_object - contains all header and data information for a slave * data object * @type: Object type * @version: Object version * @manufacturer_id: Manufacturer ID number allocated by MIPI * @length: Length of the entire object including header and CRC; * data length == total length - 8. * @data: Raw byte data found in the object * @crc: CRC of the object calculated using CRC-CCITT * @list: Linked-list connection parameter; internal use only * @addr: BIF slave address correspond to the start of the object * * manufacturer_id == 0x0000 if MIPI type and version. */ struct bif_object { u8 type; u8 version; u16 manufacturer_id; u16 length; u8 *data; u16 crc; struct list_head list; u16 addr; }; /** * struct bif_nvm_function - constant data present in non-volatile memory * function as well internal software state * parameters * @nvm_pointer: BIF slave address where NVM registers begin * @slave_control_channel: Slave control channel associated with the * NVM function. This channel is also the task * number. * @write_buffer_size: Size in bytes of the NVM write buffer. 0x00 * is used to denote a 256 byte buffer. * @nvm_base_address: BIF slave address where NVM begins * @nvm_size: NVM size in bytes * @nvm_lock_offset: Offset from the beginning of NVM of the first * writable address * @object_count: Number of BIF objects read from NVM * @object_list: List of BIF objects read from NVM */ struct bif_nvm_function { u16 nvm_pointer; u8 slave_control_channel; u8 write_buffer_size; u16 nvm_base_address; u16 nvm_size; u16 nvm_lock_offset; int object_count; struct list_head object_list; }; /** * struct bif_ctrl - Opaque handle for a BIF controller to be used in bus * oriented BIF function calls. */ struct bif_ctrl; /** * struct bif_slave - Opaque handle for a BIF slave to be used in slave oriented * BIF function calls. */ struct bif_slave; /** * enum bif_bus_state - indicates the current or desired state of the BIF bus * %BIF_BUS_STATE_MASTER_DISABLED: BIF host hardware is disabled * %BIF_BUS_STATE_POWER_DOWN: BIF bus is in power down state and * BCL is not being pulled high * %BIF_BUS_STATE_STANDBY: BIF slaves are in standby state in which * less power is drawn * %BIF_BUS_STATE_ACTIVE: BIF slaves are ready for immediate * communications * %BIF_BUS_STATE_INTERRUPT: BIF bus is active, but no communication * is possible. Instead, either one of the * slaves or the master must transition to * active state by pulling BCL low for 1 * tau bif period. */ enum bif_bus_state { BIF_BUS_STATE_MASTER_DISABLED, BIF_BUS_STATE_POWER_DOWN, BIF_BUS_STATE_STANDBY, BIF_BUS_STATE_ACTIVE, BIF_BUS_STATE_INTERRUPT, }; /** * enum bif_bus_event - events that the BIF framework may send to BIF consumers * %BIF_BUS_EVENT_BATTERY_INSERTED: Indicates that a battery was just * inserted physically or that the BIF * host controller for the battery just * probed and a battery was already * present. * %BIF_BUS_EVENT_BATTERY_REMOVED: Indicates that a battery was just * removed and thus its slaves are no * longer accessible. */ enum bif_bus_event { BIF_BUS_EVENT_BATTERY_INSERTED, BIF_BUS_EVENT_BATTERY_REMOVED, }; /* Mask values to be ORed together for use in bif_match_criteria.match_mask. */ #define BIF_MATCH_MANUFACTURER_ID BIT(0) #define BIF_MATCH_PRODUCT_ID BIT(1) #define BIF_MATCH_FUNCTION_TYPE BIT(2) #define BIF_MATCH_FUNCTION_VERSION BIT(3) #define BIF_MATCH_IGNORE_PRESENCE BIT(4) #define BIF_MATCH_OBJ_TYPE BIT(5) #define BIF_MATCH_OBJ_VERSION BIT(6) #define BIF_MATCH_OBJ_MANUFACTURER_ID BIT(7) /** * struct bif_match_criteria - specifies the matching criteria that a BIF * consumer uses to find an appropriate BIF slave * @match_mask: Mask value specifying which parameters to match upon. * This value should be some ORed combination of * BIF_MATCH_* specified above. * @manufacturer_id: Manufacturer ID number allocated by MIPI * @product_id: Manufacturer specified product ID number * @function_type: Defines the type of the function. The type may be * either MIPI or manufacturer defined. * @function_version: Defines the version of the function. The version may * be either MIPI or manufacturer defined. * @ignore_presence: If true, then slaves that are currently not present * will be successfully matched against. By default, only * present slaves can be matched. * @obj_type: Defines the type of a BIF object found in the * non-volatile memory of a slave. * @obj_version: Defines the version of a BIF object found in the * non-volatile memory of a slave. * @obj_manufacturer_id: Manufacturer ID of a BIF object found in the * non-volatile memory of a slave. * * If function_type and function_verion are both specified, then they must both * match for a single BIF function. If obj_type and obj_version or * obj_manufacturer_id are specified, then all must match for a single BIF * object. */ struct bif_match_criteria { u32 match_mask; u16 manufacturer_id; u16 product_id; u8 function_type; u8 function_version; bool ignore_presence; u8 obj_type; u8 obj_version; u16 obj_manufacturer_id; }; /* Mask values to be ORed for use in bif_obj_match_criteria.match_mask. */ #define BIF_OBJ_MATCH_TYPE BIT(0) #define BIF_OBJ_MATCH_VERSION BIT(1) #define BIF_OBJ_MATCH_MANUFACTURER_ID BIT(2) /** * struct bif_obj_match_criteria - specifies the matching criteria that a BIF * consumer uses to find an appropriate BIF data object * within a slave * @match_mask: Mask value specifying which parameters to match upon. * This value should be some ORed combination of * BIF_OBJ_MATCH_* specified above. * @type: Defines the type of the object. The type may be either * MIPI or manufacturer defined. * @version: Defines the version of the object. The version may be * either MIPI or manufacturer defined. * @manufacturer_id: Manufacturer ID number allocated by MIPI. */ struct bif_obj_match_criteria { u32 match_mask; u8 type; u8 version; u16 manufacturer_id; }; /** * bif_battery_rid_ranges - MIPI-BIF defined Rid battery pack resistance ranges * %BIF_BATT_RID_SPECIAL1_MIN: Minimum Rid for special case 1 * %BIF_BATT_RID_SPECIAL1_MAX: Maximum Rid for special case 1 * %BIF_BATT_RID_SPECIAL2_MIN: Minimum Rid for special case 2 * %BIF_BATT_RID_SPECIAL2_MAX: Maximum Rid for special case 2 * %BIF_BATT_RID_SPECIAL3_MIN: Minimum Rid for special case 3 * %BIF_BATT_RID_SPECIAL3_MAX: Maximum Rid for special case 3 * %BIF_BATT_RID_LOW_COST_MIN: Minimum Rid for a low cost battery pack * %BIF_BATT_RID_LOW_COST_MAX: Maximum Rid for a low cost battery pack * %BIF_BATT_RID_SMART_MIN: Minimum Rid for a smart battery pack * %BIF_BATT_RID_SMART_MAX: Maximum Rid for a smart battery pack */ enum bif_battery_rid_ranges { BIF_BATT_RID_SPECIAL1_MIN = 0, BIF_BATT_RID_SPECIAL1_MAX = 1, BIF_BATT_RID_SPECIAL2_MIN = 7350, BIF_BATT_RID_SPECIAL2_MAX = 7650, BIF_BATT_RID_SPECIAL3_MIN = 12740, BIF_BATT_RID_SPECIAL3_MAX = 13260, BIF_BATT_RID_LOW_COST_MIN = 19600, BIF_BATT_RID_LOW_COST_MAX = 140000, BIF_BATT_RID_SMART_MIN = 240000, BIF_BATT_RID_SMART_MAX = 450000, }; #ifdef CONFIG_BIF int bif_request_irq(struct bif_slave *slave, unsigned int task, struct notifier_block *nb); int bif_free_irq(struct bif_slave *slave, unsigned int task, struct notifier_block *nb); int bif_trigger_task(struct bif_slave *slave, unsigned int task); int bif_enable_auto_task(struct bif_slave *slave, unsigned int task); int bif_disable_auto_task(struct bif_slave *slave, unsigned int task); int bif_task_is_busy(struct bif_slave *slave, unsigned int task); int bif_ctrl_count(void); struct bif_ctrl *bif_ctrl_get_by_id(unsigned int id); struct bif_ctrl *bif_ctrl_get(struct device *consumer_dev); void bif_ctrl_put(struct bif_ctrl *ctrl); int bif_ctrl_signal_battery_changed(struct bif_ctrl *ctrl); int bif_slave_match_count(struct bif_ctrl *ctrl, const struct bif_match_criteria *match_criteria); struct bif_slave *bif_slave_match_get(struct bif_ctrl *ctrl, unsigned int id, const struct bif_match_criteria *match_criteria); void bif_slave_put(struct bif_slave *slave); int bif_ctrl_notifier_register(struct bif_ctrl *ctrl, struct notifier_block *nb); int bif_ctrl_notifier_unregister(struct bif_ctrl *ctrl, struct notifier_block *nb); struct bif_ctrl *bif_get_ctrl_handle(struct bif_slave *slave); int bif_slave_find_function(struct bif_slave *slave, u8 function, u8 *version, u16 *function_pointer); int bif_object_match_count(struct bif_slave *slave, const struct bif_obj_match_criteria *match_criteria); struct bif_object *bif_object_match_get(struct bif_slave *slave, unsigned int id, const struct bif_obj_match_criteria *match_criteria); void bif_object_put(struct bif_object *object); int bif_slave_read(struct bif_slave *slave, u16 addr, u8 *buf, int len); int bif_slave_write(struct bif_slave *slave, u16 addr, u8 *buf, int len); int bif_slave_nvm_raw_read(struct bif_slave *slave, u16 offset, u8 *buf, int len); int bif_slave_nvm_raw_write(struct bif_slave *slave, u16 offset, u8 *buf, int len); int bif_object_write(struct bif_slave *slave, u8 type, u8 version, u16 manufacturer_id, const u8 *data, int data_len); int bif_object_overwrite(struct bif_slave *slave, struct bif_object *object, u8 type, u8 version, u16 manufacturer_id, const u8 *data, int data_len); int bif_object_delete(struct bif_slave *slave, const struct bif_object *object); int bif_slave_is_present(struct bif_slave *slave); int bif_slave_is_selected(struct bif_slave *slave); int bif_slave_select(struct bif_slave *slave); int bif_ctrl_raw_transaction(struct bif_ctrl *ctrl, int transaction, u8 data); int bif_ctrl_raw_transaction_read(struct bif_ctrl *ctrl, int transaction, u8 data, int *response); int bif_ctrl_raw_transaction_query(struct bif_ctrl *ctrl, int transaction, u8 data, bool *query_response); void bif_ctrl_bus_lock(struct bif_ctrl *ctrl); void bif_ctrl_bus_unlock(struct bif_ctrl *ctrl); u16 bif_crc_ccitt(const u8 *buffer, unsigned int len); int bif_ctrl_measure_rid(struct bif_ctrl *ctrl); int bif_ctrl_get_bus_period(struct bif_ctrl *ctrl); int bif_ctrl_set_bus_period(struct bif_ctrl *ctrl, int period_ns); int bif_ctrl_get_bus_state(struct bif_ctrl *ctrl); int bif_ctrl_set_bus_state(struct bif_ctrl *ctrl, enum bif_bus_state state); #else static inline int bif_request_irq(struct bif_slave *slave, unsigned int task, struct notifier_block *nb) { return -EPERM; } static inline int bif_free_irq(struct bif_slave *slave, unsigned int task, struct notifier_block *nb) { return -EPERM; } static inline int bif_trigger_task(struct bif_slave *slave, unsigned int task) { return -EPERM; } static inline int bif_enable_auto_task(struct bif_slave *slave, unsigned int task) { return -EPERM; } static inline int bif_disable_auto_task(struct bif_slave *slave, unsigned int task) { return -EPERM; } static inline int bif_task_is_busy(struct bif_slave *slave, unsigned int task) { return -EPERM; } static inline int bif_ctrl_count(void) { return -EPERM; } static inline struct bif_ctrl *bif_ctrl_get_by_id(unsigned int id) { return ERR_PTR(-EPERM); } struct bif_ctrl *bif_ctrl_get(struct device *consumer_dev) { return ERR_PTR(-EPERM); } static inline void bif_ctrl_put(struct bif_ctrl *ctrl) { return; } static inline int bif_ctrl_signal_battery_changed(struct bif_ctrl *ctrl) { return -EPERM; } static inline int bif_slave_match_count(struct bif_ctrl *ctrl, const struct bif_match_criteria *match_criteria) { return -EPERM; } static inline struct bif_slave *bif_slave_match_get(struct bif_ctrl *ctrl, unsigned int id, const struct bif_match_criteria *match_criteria) { return ERR_PTR(-EPERM); } static inline void bif_slave_put(struct bif_slave *slave) { return; } static inline int bif_ctrl_notifier_register(struct bif_ctrl *ctrl, struct notifier_block *nb) { return -EPERM; } static inline int bif_ctrl_notifier_unregister(struct bif_ctrl *ctrl, struct notifier_block *nb) { return -EPERM; } static inline struct bif_ctrl *bif_get_ctrl_handle(struct bif_slave *slave) { return ERR_PTR(-EPERM); } static inline int bif_slave_find_function(struct bif_slave *slave, u8 function, u8 *version, u16 *function_pointer) { return -EPERM; } static inline int bif_object_match_count(struct bif_slave *slave, const struct bif_obj_match_criteria *match_criteria) { return -EPERM; } static inline struct bif_object *bif_object_match_get(struct bif_slave *slave, unsigned int id, const struct bif_obj_match_criteria *match_criteria) { return ERR_PTR(-EPERM); } static inline void bif_object_put(struct bif_object *object) {} static inline int bif_slave_read(struct bif_slave *slave, u16 addr, u8 *buf, int len) { return -EPERM; } static inline int bif_slave_write(struct bif_slave *slave, u16 addr, u8 *buf, int len) { return -EPERM; } static inline int bif_slave_nvm_raw_read(struct bif_slave *slave, u16 offset, u8 *buf, int len) { return -EPERM; } static inline int bif_slave_nvm_raw_write(struct bif_slave *slave, u16 offset, u8 *buf, int len) { return -EPERM; } static inline int bif_object_write(struct bif_slave *slave, u8 type, u8 version, u16 manufacturer_id, const u8 *data, int data_len) { return -EPERM; } static inline int bif_object_overwrite(struct bif_slave *slave, struct bif_object *object, u8 type, u8 version, u16 manufacturer_id, const u8 *data, int data_len) { return -EPERM; } static inline int bif_object_delete(struct bif_slave *slave, const struct bif_object *object) { return -EPERM; } static inline int bif_slave_is_present(struct bif_slave *slave) { return -EPERM; } static inline int bif_slave_is_selected(struct bif_slave *slave) { return -EPERM; } static inline int bif_slave_select(struct bif_slave *slave) { return -EPERM; } static inline int bif_ctrl_raw_transaction(struct bif_ctrl *ctrl, int transaction, u8 data) { return -EPERM; } static inline int bif_ctrl_raw_transaction_read(struct bif_ctrl *ctrl, int transaction, u8 data, int *response) { return -EPERM; } static inline int bif_ctrl_raw_transaction_query(struct bif_ctrl *ctrl, int transaction, u8 data, bool *query_response) { return -EPERM; } static inline void bif_ctrl_bus_lock(struct bif_ctrl *ctrl) { return -EPERM; } static inline void bif_ctrl_bus_unlock(struct bif_ctrl *ctrl) { return -EPERM; } static inline u16 bif_crc_ccitt(const u8 *buffer, unsigned int len) { return 0; } static inline int bif_ctrl_measure_rid(struct bif_ctrl *ctrl) { return -EPERM; } static inline int bif_ctrl_get_bus_period(struct bif_ctrl *ctrl) { return -EPERM; } static inline int bif_ctrl_set_bus_period(struct bif_ctrl *ctrl, int period_ns) { return -EPERM; } static inline int bif_ctrl_get_bus_state(struct bif_ctrl *ctrl) { return -EPERM; } static inline int bif_ctrl_set_bus_state(struct bif_ctrl *ctrl, enum bif_bus_state state) { return -EPERM; } #endif #endif