include/linux/rmi.h - third_party/kernel - Git at Google

 /* SPDX-License-Identifier: GPL-2.0-only */
 /*
  * Copyright (c) 2011-2016 Synaptics Incorporated
  * Copyright (c) 2011 Unixphere
  */

 #ifndef _RMI_H
 #define _RMI_H
 #include <linux/kernel.h>
 #include <linux/device.h>
 #include <linux/interrupt.h>
 #include <linux/input.h>
 #include <linux/kfifo.h>
 #include <linux/list.h>
 #include <linux/module.h>
 #include <linux/types.h>

 #define NAME_BUFFER_SIZE 256

 /**
  * struct rmi_2d_axis_alignment - target axis alignment
  * @swap_axes: set to TRUE if desired to swap x- and y-axis
  * @flip_x: set to TRUE if desired to flip direction on x-axis
  * @flip_y: set to TRUE if desired to flip direction on y-axis
  * @clip_x_low - reported X coordinates below this setting will be clipped to
  *               the specified value
  * @clip_x_high - reported X coordinates above this setting will be clipped to
  *               the specified value
  * @clip_y_low - reported Y coordinates below this setting will be clipped to
  *               the specified value
  * @clip_y_high - reported Y coordinates above this setting will be clipped to
  *               the specified value
  * @offset_x - this value will be added to all reported X coordinates
  * @offset_y - this value will be added to all reported Y coordinates
  * @rel_report_enabled - if set to true, the relative reporting will be
  *               automatically enabled for this sensor.
  */
 struct rmi_2d_axis_alignment {
 	bool swap_axes;
 	bool flip_x;
 	bool flip_y;
 	u16 clip_x_low;
 	u16 clip_y_low;
 	u16 clip_x_high;
 	u16 clip_y_high;
 	u16 offset_x;
 	u16 offset_y;
 	u8 delta_x_threshold;
 	u8 delta_y_threshold;
 };

 /** This is used to override any hints an F11 2D sensor might have provided
  * as to what type of sensor it is.
  *
  * @rmi_f11_sensor_default - do not override, determine from F11_2D_QUERY14 if
  * available.
  * @rmi_f11_sensor_touchscreen - treat the sensor as a touchscreen (direct
  * pointing).
  * @rmi_f11_sensor_touchpad - thread the sensor as a touchpad (indirect
  * pointing).
  */
 enum rmi_sensor_type {
 	rmi_sensor_default = 0,
 	rmi_sensor_touchscreen,
 	rmi_sensor_touchpad
 };

 #define RMI_F11_DISABLE_ABS_REPORT      BIT(0)

 /**
  * struct rmi_2d_sensor_data - overrides defaults for a 2D sensor.
  * @axis_align - provides axis alignment overrides (see above).
  * @sensor_type - Forces the driver to treat the sensor as an indirect
  * pointing device (touchpad) rather than a direct pointing device
  * (touchscreen).  This is useful when F11_2D_QUERY14 register is not
  * available.
  * @disable_report_mask - Force data to not be reported even if it is supported
  * by the firware.
  * @topbuttonpad - Used with the "5 buttons touchpads" found on the Lenovo 40
  * series
  * @kernel_tracking - most moderns RMI f11 firmwares implement Multifinger
  * Type B protocol. However, there are some corner cases where the user
  * triggers some jumps by tapping with two fingers on the touchpad.
  * Use this setting and dmax to filter out these jumps.
  * Also, when using an old sensor using MF Type A behavior, set to true to
  * report an actual MT protocol B.
  * @dmax - the maximum distance (in sensor units) the kernel tracking allows two
  * distincts fingers to be considered the same.
  */
 struct rmi_2d_sensor_platform_data {
 	struct rmi_2d_axis_alignment axis_align;
 	enum rmi_sensor_type sensor_type;
 	int x_mm;
 	int y_mm;
 	int disable_report_mask;
 	u16 rezero_wait;
 	bool topbuttonpad;
 	bool kernel_tracking;
 	int dmax;
 	int dribble;
 	int palm_detect;
 };

 /**
  * struct rmi_gpio_data - overrides defaults for a single F30/F3A GPIOs/LED
  * chip.
  * @buttonpad - the touchpad is a buttonpad, so enable only the first actual
  * button that is found.
  * @trackstick_buttons - Set when the function 30 or 3a is handling the physical
  * buttons of the trackstick (as a PS/2 passthrough device).
  * @disable - the touchpad incorrectly reports F30/F3A and it should be ignored.
  * This is a special case which is due to misconfigured firmware.
  */
 struct rmi_gpio_data {
 	bool buttonpad;
 	bool trackstick_buttons;
 	bool disable;
 };


 /*
  * Set the state of a register
  *	DEFAULT - use the default value set by the firmware config
  *	OFF - explicitly disable the register
  *	ON - explicitly enable the register
  */
 enum rmi_reg_state {
 	RMI_REG_STATE_DEFAULT = 0,
 	RMI_REG_STATE_OFF = 1,
 	RMI_REG_STATE_ON = 2
 };

 /**
  * struct rmi_f01_power_management -When non-zero, these values will be written
  * to the touch sensor to override the default firmware settigns.  For a
  * detailed explanation of what each field does, see the corresponding
  * documention in the RMI4 specification.
  *
  * @nosleep - specifies whether the device is permitted to sleep or doze (that
  * is, enter a temporary low power state) when no fingers are touching the
  * sensor.
  * @wakeup_threshold - controls the capacitance threshold at which the touch
  * sensor will decide to wake up from that low power state.
  * @doze_holdoff - controls how long the touch sensor waits after the last
  * finger lifts before entering the doze state, in units of 100ms.
  * @doze_interval - controls the interval between checks for finger presence
  * when the touch sensor is in doze mode, in units of 10ms.
  */
 struct rmi_f01_power_management {
 	enum rmi_reg_state nosleep;
 	u8 wakeup_threshold;
 	u8 doze_holdoff;
 	u8 doze_interval;
 };

 /**
  * struct rmi_device_platform_data_spi - provides parameters used in SPI
  * communications.  All Synaptics SPI products support a standard SPI
  * interface; some also support what is called SPI V2 mode, depending on
  * firmware and/or ASIC limitations.  In V2 mode, the touch sensor can
  * support shorter delays during certain operations, and these are specified
  * separately from the standard mode delays.
  *
  * @block_delay - for standard SPI transactions consisting of both a read and
  * write operation, the delay (in microseconds) between the read and write
  * operations.
  * @split_read_block_delay_us - for V2 SPI transactions consisting of both a
  * read and write operation, the delay (in microseconds) between the read and
  * write operations.
  * @read_delay_us - the delay between each byte of a read operation in normal
  * SPI mode.
  * @write_delay_us - the delay between each byte of a write operation in normal
  * SPI mode.
  * @split_read_byte_delay_us - the delay between each byte of a read operation
  * in V2 mode.
  * @pre_delay_us - the delay before the start of a SPI transaction.  This is
  * typically useful in conjunction with custom chip select assertions (see
  * below).
  * @post_delay_us - the delay after the completion of an SPI transaction.  This
  * is typically useful in conjunction with custom chip select assertions (see
  * below).
  * @cs_assert - For systems where the SPI subsystem does not control the CS/SSB
  * line, or where such control is broken, you can provide a custom routine to
  * handle a GPIO as CS/SSB.  This routine will be called at the beginning and
  * end of each SPI transaction.  The RMI SPI implementation will wait
  * pre_delay_us after this routine returns before starting the SPI transfer;
  * and post_delay_us after completion of the SPI transfer(s) before calling it
  * with assert==FALSE.
  */
 struct rmi_device_platform_data_spi {
 	u32 block_delay_us;
 	u32 split_read_block_delay_us;
 	u32 read_delay_us;
 	u32 write_delay_us;
 	u32 split_read_byte_delay_us;
 	u32 pre_delay_us;
 	u32 post_delay_us;
 	u8 bits_per_word;
 	u16 mode;

 	void *cs_assert_data;
 	int (*cs_assert)(const void *cs_assert_data, const bool assert);
 };

 /**
  * struct rmi_device_platform_data - system specific configuration info.
  *
  * @reset_delay_ms - after issuing a reset command to the touch sensor, the
  * driver waits a few milliseconds to give the firmware a chance to
  * re-initialize.  You can override the default wait period here.
  * @irq: irq associated with the attn gpio line, or negative
  */
 struct rmi_device_platform_data {
 	int reset_delay_ms;
 	int irq;

 	struct rmi_device_platform_data_spi spi_data;

 	/* function handler pdata */
 	struct rmi_2d_sensor_platform_data sensor_pdata;
 	struct rmi_f01_power_management power_management;
 	struct rmi_gpio_data gpio_data;
 };

 /**
  * struct rmi_function_descriptor - RMI function base addresses
  *
  * @query_base_addr: The RMI Query base address
  * @command_base_addr: The RMI Command base address
  * @control_base_addr: The RMI Control base address
  * @data_base_addr: The RMI Data base address
  * @interrupt_source_count: The number of irqs this RMI function needs
  * @function_number: The RMI function number
  *
  * This struct is used when iterating the Page Description Table. The addresses
  * are 16-bit values to include the current page address.
  *
  */
 struct rmi_function_descriptor {
 	u16 query_base_addr;
 	u16 command_base_addr;
 	u16 control_base_addr;
 	u16 data_base_addr;
 	u8 interrupt_source_count;
 	u8 function_number;
 	u8 function_version;
 };

 struct rmi_device;

 /**
  * struct rmi_transport_dev - represent an RMI transport device
  *
  * @dev: Pointer to the communication device, e.g. i2c or spi
  * @rmi_dev: Pointer to the RMI device
  * @proto_name: name of the transport protocol (SPI, i2c, etc)
  * @ops: pointer to transport operations implementation
  *
  * The RMI transport device implements the glue between different communication
  * buses such as I2C and SPI.
  *
  */
 struct rmi_transport_dev {
 	struct device *dev;
 	struct rmi_device *rmi_dev;

 	const char *proto_name;
 	const struct rmi_transport_ops *ops;

 	struct rmi_device_platform_data pdata;

 	struct input_dev *input;
 };

 /**
  * struct rmi_transport_ops - defines transport protocol operations.
  *
  * @write_block: Writing a block of data to the specified address
  * @read_block: Read a block of data from the specified address.
  */
 struct rmi_transport_ops {
 	int (*write_block)(struct rmi_transport_dev *xport, u16 addr,
 			   const void *buf, size_t len);
 	int (*read_block)(struct rmi_transport_dev *xport, u16 addr,
 			  void *buf, size_t len);
 	int (*reset)(struct rmi_transport_dev *xport, u16 reset_addr);
 };

 /**
  * struct rmi_driver - driver for an RMI4 sensor on the RMI bus.
  *
  * @driver: Device driver model driver
  * @reset_handler: Called when a reset is detected.
  * @clear_irq_bits: Clear the specified bits in the current interrupt mask.
  * @set_irq_bist: Set the specified bits in the current interrupt mask.
  * @store_productid: Callback for cache product id from function 01
  * @data: Private data pointer
  *
  */
 struct rmi_driver {
 	struct device_driver driver;

 	int (*reset_handler)(struct rmi_device *rmi_dev);
 	int (*clear_irq_bits)(struct rmi_device *rmi_dev, unsigned long *mask);
 	int (*set_irq_bits)(struct rmi_device *rmi_dev, unsigned long *mask);
 	int (*store_productid)(struct rmi_device *rmi_dev);
 	int (*set_input_params)(struct rmi_device *rmi_dev,
 			struct input_dev *input);
 	void *data;
 };

 /**
  * struct rmi_device - represents an RMI4 sensor device on the RMI bus.
  *
  * @dev: The device created for the RMI bus
  * @number: Unique number for the device on the bus.
  * @driver: Pointer to associated driver
  * @xport: Pointer to the transport interface
  *
  */
 struct rmi_device {
 	struct device dev;
 	int number;

 	struct rmi_driver *driver;
 	struct rmi_transport_dev *xport;

 };

 struct rmi4_attn_data {
 	unsigned long irq_status;
 	size_t size;
 	void *data;
 };

 struct rmi_driver_data {
 	struct list_head function_list;

 	struct rmi_device *rmi_dev;

 	struct rmi_function *f01_container;
 	struct rmi_function *f34_container;
 	bool bootloader_mode;

 	int num_of_irq_regs;
 	int irq_count;
 	void *irq_memory;
 	unsigned long *irq_status;
 	unsigned long *fn_irq_bits;
 	unsigned long *current_irq_mask;
 	unsigned long *new_irq_mask;
 	struct mutex irq_mutex;
 	struct input_dev *input;

 	struct irq_domain *irqdomain;

 	u8 pdt_props;

 	u8 num_rx_electrodes;
 	u8 num_tx_electrodes;

 	bool enabled;
 	struct mutex enabled_mutex;

 	struct rmi4_attn_data attn_data;
 	DECLARE_KFIFO(attn_fifo, struct rmi4_attn_data, 16);
 };

 int rmi_register_transport_device(struct rmi_transport_dev *xport);
 void rmi_unregister_transport_device(struct rmi_transport_dev *xport);

 void rmi_set_attn_data(struct rmi_device *rmi_dev, unsigned long irq_status,
 		       void *data, size_t size);

 int rmi_driver_suspend(struct rmi_device *rmi_dev, bool enable_wake);
 int rmi_driver_resume(struct rmi_device *rmi_dev, bool clear_wake);
 #endif
	/* SPDX-License-Identifier: GPL-2.0-only */
	/*
	* Copyright (c) 2011-2016 Synaptics Incorporated
	* Copyright (c) 2011 Unixphere
	*/

	#ifndef _RMI_H
	#define _RMI_H
	#include <linux/kernel.h>
	#include <linux/device.h>
	#include <linux/interrupt.h>
	#include <linux/input.h>
	#include <linux/kfifo.h>
	#include <linux/list.h>
	#include <linux/module.h>
	#include <linux/types.h>

	#define NAME_BUFFER_SIZE 256

	/**
	* struct rmi_2d_axis_alignment - target axis alignment
	* @swap_axes: set to TRUE if desired to swap x- and y-axis
	* @flip_x: set to TRUE if desired to flip direction on x-axis
	* @flip_y: set to TRUE if desired to flip direction on y-axis
	* @clip_x_low - reported X coordinates below this setting will be clipped to
	* the specified value
	* @clip_x_high - reported X coordinates above this setting will be clipped to
	* the specified value
	* @clip_y_low - reported Y coordinates below this setting will be clipped to
	* the specified value
	* @clip_y_high - reported Y coordinates above this setting will be clipped to
	* the specified value
	* @offset_x - this value will be added to all reported X coordinates
	* @offset_y - this value will be added to all reported Y coordinates
	* @rel_report_enabled - if set to true, the relative reporting will be
	* automatically enabled for this sensor.
	*/
	struct rmi_2d_axis_alignment {
	bool swap_axes;
	bool flip_x;
	bool flip_y;
	u16 clip_x_low;
	u16 clip_y_low;
	u16 clip_x_high;
	u16 clip_y_high;
	u16 offset_x;
	u16 offset_y;
	u8 delta_x_threshold;
	u8 delta_y_threshold;
	};

	/** This is used to override any hints an F11 2D sensor might have provided
	* as to what type of sensor it is.
	*
	* @rmi_f11_sensor_default - do not override, determine from F11_2D_QUERY14 if
	* available.
	* @rmi_f11_sensor_touchscreen - treat the sensor as a touchscreen (direct
	* pointing).
	* @rmi_f11_sensor_touchpad - thread the sensor as a touchpad (indirect
	* pointing).
	*/
	enum rmi_sensor_type {
	rmi_sensor_default = 0,
	rmi_sensor_touchscreen,
	rmi_sensor_touchpad
	};

	#define RMI_F11_DISABLE_ABS_REPORT BIT(0)

	/**
	* struct rmi_2d_sensor_data - overrides defaults for a 2D sensor.
	* @axis_align - provides axis alignment overrides (see above).
	* @sensor_type - Forces the driver to treat the sensor as an indirect
	* pointing device (touchpad) rather than a direct pointing device
	* (touchscreen). This is useful when F11_2D_QUERY14 register is not
	* available.
	* @disable_report_mask - Force data to not be reported even if it is supported
	* by the firware.
	* @topbuttonpad - Used with the "5 buttons touchpads" found on the Lenovo 40
	* series
	* @kernel_tracking - most moderns RMI f11 firmwares implement Multifinger
	* Type B protocol. However, there are some corner cases where the user
	* triggers some jumps by tapping with two fingers on the touchpad.
	* Use this setting and dmax to filter out these jumps.
	* Also, when using an old sensor using MF Type A behavior, set to true to
	* report an actual MT protocol B.
	* @dmax - the maximum distance (in sensor units) the kernel tracking allows two
	* distincts fingers to be considered the same.
	*/
	struct rmi_2d_sensor_platform_data {
	struct rmi_2d_axis_alignment axis_align;
	enum rmi_sensor_type sensor_type;
	int x_mm;
	int y_mm;
	int disable_report_mask;
	u16 rezero_wait;
	bool topbuttonpad;
	bool kernel_tracking;
	int dmax;
	int dribble;
	int palm_detect;
	};

	/**
	* struct rmi_gpio_data - overrides defaults for a single F30/F3A GPIOs/LED
	* chip.
	* @buttonpad - the touchpad is a buttonpad, so enable only the first actual
	* button that is found.
	* @trackstick_buttons - Set when the function 30 or 3a is handling the physical
	* buttons of the trackstick (as a PS/2 passthrough device).
	* @disable - the touchpad incorrectly reports F30/F3A and it should be ignored.
	* This is a special case which is due to misconfigured firmware.
	*/
	struct rmi_gpio_data {
	bool buttonpad;
	bool trackstick_buttons;
	bool disable;
	};


	/*
	* Set the state of a register
	* DEFAULT - use the default value set by the firmware config
	* OFF - explicitly disable the register
	* ON - explicitly enable the register
	*/
	enum rmi_reg_state {
	RMI_REG_STATE_DEFAULT = 0,
	RMI_REG_STATE_OFF = 1,
	RMI_REG_STATE_ON = 2
	};

	/**
	* struct rmi_f01_power_management -When non-zero, these values will be written
	* to the touch sensor to override the default firmware settigns. For a
	* detailed explanation of what each field does, see the corresponding
	* documention in the RMI4 specification.
	*
	* @nosleep - specifies whether the device is permitted to sleep or doze (that
	* is, enter a temporary low power state) when no fingers are touching the
	* sensor.
	* @wakeup_threshold - controls the capacitance threshold at which the touch
	* sensor will decide to wake up from that low power state.
	* @doze_holdoff - controls how long the touch sensor waits after the last
	* finger lifts before entering the doze state, in units of 100ms.
	* @doze_interval - controls the interval between checks for finger presence
	* when the touch sensor is in doze mode, in units of 10ms.
	*/
	struct rmi_f01_power_management {
	enum rmi_reg_state nosleep;
	u8 wakeup_threshold;
	u8 doze_holdoff;
	u8 doze_interval;
	};

	/**
	* struct rmi_device_platform_data_spi - provides parameters used in SPI
	* communications. All Synaptics SPI products support a standard SPI
	* interface; some also support what is called SPI V2 mode, depending on
	* firmware and/or ASIC limitations. In V2 mode, the touch sensor can
	* support shorter delays during certain operations, and these are specified
	* separately from the standard mode delays.
	*
	* @block_delay - for standard SPI transactions consisting of both a read and
	* write operation, the delay (in microseconds) between the read and write
	* operations.
	* @split_read_block_delay_us - for V2 SPI transactions consisting of both a
	* read and write operation, the delay (in microseconds) between the read and
	* write operations.
	* @read_delay_us - the delay between each byte of a read operation in normal
	* SPI mode.
	* @write_delay_us - the delay between each byte of a write operation in normal
	* SPI mode.
	* @split_read_byte_delay_us - the delay between each byte of a read operation
	* in V2 mode.
	* @pre_delay_us - the delay before the start of a SPI transaction. This is
	* typically useful in conjunction with custom chip select assertions (see
	* below).
	* @post_delay_us - the delay after the completion of an SPI transaction. This
	* is typically useful in conjunction with custom chip select assertions (see
	* below).
	* @cs_assert - For systems where the SPI subsystem does not control the CS/SSB
	* line, or where such control is broken, you can provide a custom routine to
	* handle a GPIO as CS/SSB. This routine will be called at the beginning and
	* end of each SPI transaction. The RMI SPI implementation will wait
	* pre_delay_us after this routine returns before starting the SPI transfer;
	* and post_delay_us after completion of the SPI transfer(s) before calling it
	* with assert==FALSE.
	*/
	struct rmi_device_platform_data_spi {
	u32 block_delay_us;
	u32 split_read_block_delay_us;
	u32 read_delay_us;
	u32 write_delay_us;
	u32 split_read_byte_delay_us;
	u32 pre_delay_us;
	u32 post_delay_us;
	u8 bits_per_word;
	u16 mode;

	void *cs_assert_data;
	int (cs_assert)(const void cs_assert_data, const bool assert);
	};

	/**
	* struct rmi_device_platform_data - system specific configuration info.
	*
	* @reset_delay_ms - after issuing a reset command to the touch sensor, the
	* driver waits a few milliseconds to give the firmware a chance to
	* re-initialize. You can override the default wait period here.
	* @irq: irq associated with the attn gpio line, or negative
	*/
	struct rmi_device_platform_data {
	int reset_delay_ms;
	int irq;

	struct rmi_device_platform_data_spi spi_data;

	/* function handler pdata */
	struct rmi_2d_sensor_platform_data sensor_pdata;
	struct rmi_f01_power_management power_management;
	struct rmi_gpio_data gpio_data;
	};

	/**
	* struct rmi_function_descriptor - RMI function base addresses
	*
	* @query_base_addr: The RMI Query base address
	* @command_base_addr: The RMI Command base address
	* @control_base_addr: The RMI Control base address
	* @data_base_addr: The RMI Data base address
	* @interrupt_source_count: The number of irqs this RMI function needs
	* @function_number: The RMI function number
	*
	* This struct is used when iterating the Page Description Table. The addresses
	* are 16-bit values to include the current page address.
	*
	*/
	struct rmi_function_descriptor {
	u16 query_base_addr;
	u16 command_base_addr;
	u16 control_base_addr;
	u16 data_base_addr;
	u8 interrupt_source_count;
	u8 function_number;
	u8 function_version;
	};

	struct rmi_device;

	/**
	* struct rmi_transport_dev - represent an RMI transport device
	*
	* @dev: Pointer to the communication device, e.g. i2c or spi
	* @rmi_dev: Pointer to the RMI device
	* @proto_name: name of the transport protocol (SPI, i2c, etc)
	* @ops: pointer to transport operations implementation
	*
	* The RMI transport device implements the glue between different communication
	* buses such as I2C and SPI.
	*
	*/
	struct rmi_transport_dev {
	struct device *dev;
	struct rmi_device *rmi_dev;

	const char *proto_name;
	const struct rmi_transport_ops *ops;

	struct rmi_device_platform_data pdata;

	struct input_dev *input;
	};

	/**
	* struct rmi_transport_ops - defines transport protocol operations.
	*
	* @write_block: Writing a block of data to the specified address
	* @read_block: Read a block of data from the specified address.
	*/
	struct rmi_transport_ops {
	int (write_block)(struct rmi_transport_dev xport, u16 addr,
	const void *buf, size_t len);
	int (read_block)(struct rmi_transport_dev xport, u16 addr,
	void *buf, size_t len);
	int (reset)(struct rmi_transport_dev xport, u16 reset_addr);
	};

	/**
	* struct rmi_driver - driver for an RMI4 sensor on the RMI bus.
	*
	* @driver: Device driver model driver
	* @reset_handler: Called when a reset is detected.
	* @clear_irq_bits: Clear the specified bits in the current interrupt mask.
	* @set_irq_bist: Set the specified bits in the current interrupt mask.
	* @store_productid: Callback for cache product id from function 01
	* @data: Private data pointer
	*
	*/
	struct rmi_driver {
	struct device_driver driver;

	int (reset_handler)(struct rmi_device rmi_dev);
	int (clear_irq_bits)(struct rmi_device rmi_dev, unsigned long *mask);
	int (set_irq_bits)(struct rmi_device rmi_dev, unsigned long *mask);
	int (store_productid)(struct rmi_device rmi_dev);
	int (set_input_params)(struct rmi_device rmi_dev,
	struct input_dev *input);
	void *data;
	};

	/**
	* struct rmi_device - represents an RMI4 sensor device on the RMI bus.
	*
	* @dev: The device created for the RMI bus
	* @number: Unique number for the device on the bus.
	* @driver: Pointer to associated driver
	* @xport: Pointer to the transport interface
	*
	*/
	struct rmi_device {
	struct device dev;
	int number;

	struct rmi_driver *driver;
	struct rmi_transport_dev *xport;

	};

	struct rmi4_attn_data {
	unsigned long irq_status;
	size_t size;
	void *data;
	};

	struct rmi_driver_data {
	struct list_head function_list;

	struct rmi_device *rmi_dev;

	struct rmi_function *f01_container;
	struct rmi_function *f34_container;
	bool bootloader_mode;

	int num_of_irq_regs;
	int irq_count;
	void *irq_memory;
	unsigned long *irq_status;
	unsigned long *fn_irq_bits;
	unsigned long *current_irq_mask;
	unsigned long *new_irq_mask;
	struct mutex irq_mutex;
	struct input_dev *input;

	struct irq_domain *irqdomain;

	u8 pdt_props;

	u8 num_rx_electrodes;
	u8 num_tx_electrodes;

	bool enabled;
	struct mutex enabled_mutex;

	struct rmi4_attn_data attn_data;
	DECLARE_KFIFO(attn_fifo, struct rmi4_attn_data, 16);
	};

	int rmi_register_transport_device(struct rmi_transport_dev *xport);
	void rmi_unregister_transport_device(struct rmi_transport_dev *xport);

	void rmi_set_attn_data(struct rmi_device *rmi_dev, unsigned long irq_status,
	void *data, size_t size);

	int rmi_driver_suspend(struct rmi_device *rmi_dev, bool enable_wake);
	int rmi_driver_resume(struct rmi_device *rmi_dev, bool clear_wake);
	#endif