drivers/input/rmi4/rmi_f01.c - linux - Git at Google

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

 #include <linux/kernel.h>
 #include <linux/rmi.h>
 #include <linux/slab.h>
 #include <linux/uaccess.h>
 #include <linux/of.h>
 #include <asm/unaligned.h>
 #include "rmi_driver.h"

 #define RMI_PRODUCT_ID_LENGTH    10
 #define RMI_PRODUCT_INFO_LENGTH   2

 #define RMI_DATE_CODE_LENGTH      3

 #define PRODUCT_ID_OFFSET 0x10
 #define PRODUCT_INFO_OFFSET 0x1E


 /* Force a firmware reset of the sensor */
 #define RMI_F01_CMD_DEVICE_RESET	1

 /* Various F01_RMI_QueryX bits */

 #define RMI_F01_QRY1_CUSTOM_MAP		BIT(0)
 #define RMI_F01_QRY1_NON_COMPLIANT	BIT(1)
 #define RMI_F01_QRY1_HAS_LTS		BIT(2)
 #define RMI_F01_QRY1_HAS_SENSOR_ID	BIT(3)
 #define RMI_F01_QRY1_HAS_CHARGER_INP	BIT(4)
 #define RMI_F01_QRY1_HAS_ADJ_DOZE	BIT(5)
 #define RMI_F01_QRY1_HAS_ADJ_DOZE_HOFF	BIT(6)
 #define RMI_F01_QRY1_HAS_QUERY42	BIT(7)

 #define RMI_F01_QRY5_YEAR_MASK		0x1f
 #define RMI_F01_QRY6_MONTH_MASK		0x0f
 #define RMI_F01_QRY7_DAY_MASK		0x1f

 #define RMI_F01_QRY2_PRODINFO_MASK	0x7f

 #define RMI_F01_BASIC_QUERY_LEN		21 /* From Query 00 through 20 */

 struct f01_basic_properties {
 	u8 manufacturer_id;
 	bool has_lts;
 	bool has_adjustable_doze;
 	bool has_adjustable_doze_holdoff;
 	char dom[11]; /* YYYY/MM/DD + '\0' */
 	u8 product_id[RMI_PRODUCT_ID_LENGTH + 1];
 	u16 productinfo;
 	u32 firmware_id;
 	u32 package_id;
 };

 /* F01 device status bits */

 /* Most recent device status event */
 #define RMI_F01_STATUS_CODE(status)		((status) & 0x0f)
 /* The device has lost its configuration for some reason. */
 #define RMI_F01_STATUS_UNCONFIGURED(status)	(!!((status) & 0x80))
 /* The device is in bootloader mode */
 #define RMI_F01_STATUS_BOOTLOADER(status)	((status) & 0x40)

 /* Control register bits */

 /*
  * Sleep mode controls power management on the device and affects all
  * functions of the device.
  */
 #define RMI_F01_CTRL0_SLEEP_MODE_MASK	0x03

 #define RMI_SLEEP_MODE_NORMAL		0x00
 #define RMI_SLEEP_MODE_SENSOR_SLEEP	0x01
 #define RMI_SLEEP_MODE_RESERVED0	0x02
 #define RMI_SLEEP_MODE_RESERVED1	0x03

 /*
  * This bit disables whatever sleep mode may be selected by the sleep_mode
  * field and forces the device to run at full power without sleeping.
  */
 #define RMI_F01_CTRL0_NOSLEEP_BIT	BIT(2)

 /*
  * When this bit is set, the touch controller employs a noise-filtering
  * algorithm designed for use with a connected battery charger.
  */
 #define RMI_F01_CTRL0_CHARGER_BIT	BIT(5)

 /*
  * Sets the report rate for the device. The effect of this setting is
  * highly product dependent. Check the spec sheet for your particular
  * touch sensor.
  */
 #define RMI_F01_CTRL0_REPORTRATE_BIT	BIT(6)

 /*
  * Written by the host as an indicator that the device has been
  * successfully configured.
  */
 #define RMI_F01_CTRL0_CONFIGURED_BIT	BIT(7)

 /**
  * struct f01_device_control - controls basic sensor functions
  *
  * @ctrl0: see the bit definitions above.
  * @doze_interval: controls the interval between checks for finger presence
  *	when the touch sensor is in doze mode, in units of 10ms.
  * @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.
  */
 struct f01_device_control {
 	u8 ctrl0;
 	u8 doze_interval;
 	u8 wakeup_threshold;
 	u8 doze_holdoff;
 };

 struct f01_data {
 	struct f01_basic_properties properties;
 	struct f01_device_control device_control;

 	u16 doze_interval_addr;
 	u16 wakeup_threshold_addr;
 	u16 doze_holdoff_addr;

 	bool suspended;
 	bool old_nosleep;

 	unsigned int num_of_irq_regs;
 };

 static int rmi_f01_read_properties(struct rmi_device *rmi_dev,
 				   u16 query_base_addr,
 				   struct f01_basic_properties *props)
 {
 	u8 queries[RMI_F01_BASIC_QUERY_LEN];
 	int ret;
 	int query_offset = query_base_addr;
 	bool has_ds4_queries = false;
 	bool has_query42 = false;
 	bool has_sensor_id = false;
 	bool has_package_id_query = false;
 	bool has_build_id_query = false;
 	u16 prod_info_addr;
 	u8 ds4_query_len;

 	ret = rmi_read_block(rmi_dev, query_offset,
 			       queries, RMI_F01_BASIC_QUERY_LEN);
 	if (ret) {
 		dev_err(&rmi_dev->dev,
 			"Failed to read device query registers: %d\n", ret);
 		return ret;
 	}

 	prod_info_addr = query_offset + 17;
 	query_offset += RMI_F01_BASIC_QUERY_LEN;

 	/* Now parse what we got */
 	props->manufacturer_id = queries[0];

 	props->has_lts = queries[1] & RMI_F01_QRY1_HAS_LTS;
 	props->has_adjustable_doze =
 			queries[1] & RMI_F01_QRY1_HAS_ADJ_DOZE;
 	props->has_adjustable_doze_holdoff =
 			queries[1] & RMI_F01_QRY1_HAS_ADJ_DOZE_HOFF;
 	has_query42 = queries[1] & RMI_F01_QRY1_HAS_QUERY42;
 	has_sensor_id = queries[1] & RMI_F01_QRY1_HAS_SENSOR_ID;

 	snprintf(props->dom, sizeof(props->dom), "20%02d/%02d/%02d",
 		 queries[5] & RMI_F01_QRY5_YEAR_MASK,
 		 queries[6] & RMI_F01_QRY6_MONTH_MASK,
 		 queries[7] & RMI_F01_QRY7_DAY_MASK);

 	memcpy(props->product_id, &queries[11],
 		RMI_PRODUCT_ID_LENGTH);
 	props->product_id[RMI_PRODUCT_ID_LENGTH] = '\0';

 	props->productinfo =
 			((queries[2] & RMI_F01_QRY2_PRODINFO_MASK) << 7) |
 			(queries[3] & RMI_F01_QRY2_PRODINFO_MASK);

 	if (has_sensor_id)
 		query_offset++;

 	if (has_query42) {
 		ret = rmi_read(rmi_dev, query_offset, queries);
 		if (ret) {
 			dev_err(&rmi_dev->dev,
 				"Failed to read query 42 register: %d\n", ret);
 			return ret;
 		}

 		has_ds4_queries = !!(queries[0] & BIT(0));
 		query_offset++;
 	}

 	if (has_ds4_queries) {
 		ret = rmi_read(rmi_dev, query_offset, &ds4_query_len);
 		if (ret) {
 			dev_err(&rmi_dev->dev,
 				"Failed to read DS4 queries length: %d\n", ret);
 			return ret;
 		}
 		query_offset++;

 		if (ds4_query_len > 0) {
 			ret = rmi_read(rmi_dev, query_offset, queries);
 			if (ret) {
 				dev_err(&rmi_dev->dev,
 					"Failed to read DS4 queries: %d\n",
 					ret);
 				return ret;
 			}

 			has_package_id_query = !!(queries[0] & BIT(0));
 			has_build_id_query = !!(queries[0] & BIT(1));
 		}

 		if (has_package_id_query) {
 			ret = rmi_read_block(rmi_dev, prod_info_addr,
 					     queries, sizeof(__le64));
 			if (ret) {
 				dev_err(&rmi_dev->dev,
 					"Failed to read package info: %d\n",
 					ret);
 				return ret;
 			}

 			props->package_id = get_unaligned_le64(queries);
 			prod_info_addr++;
 		}

 		if (has_build_id_query) {
 			ret = rmi_read_block(rmi_dev, prod_info_addr, queries,
 					    3);
 			if (ret) {
 				dev_err(&rmi_dev->dev,
 					"Failed to read product info: %d\n",
 					ret);
 				return ret;
 			}

 			props->firmware_id = queries[1] << 8 | queries[0];
 			props->firmware_id += queries[2] * 65536;
 		}
 	}

 	return 0;
 }

 const char *rmi_f01_get_product_ID(struct rmi_function *fn)
 {
 	struct f01_data *f01 = dev_get_drvdata(&fn->dev);

 	return f01->properties.product_id;
 }

 static ssize_t rmi_driver_manufacturer_id_show(struct device *dev,
 					       struct device_attribute *dattr,
 					       char *buf)
 {
 	struct rmi_driver_data *data = dev_get_drvdata(dev);
 	struct f01_data *f01 = dev_get_drvdata(&data->f01_container->dev);

 	return scnprintf(buf, PAGE_SIZE, "%d\n",
 			 f01->properties.manufacturer_id);
 }

 static DEVICE_ATTR(manufacturer_id, 0444,
 		   rmi_driver_manufacturer_id_show, NULL);

 static ssize_t rmi_driver_dom_show(struct device *dev,
 				   struct device_attribute *dattr, char *buf)
 {
 	struct rmi_driver_data *data = dev_get_drvdata(dev);
 	struct f01_data *f01 = dev_get_drvdata(&data->f01_container->dev);

 	return scnprintf(buf, PAGE_SIZE, "%s\n", f01->properties.dom);
 }

 static DEVICE_ATTR(date_of_manufacture, 0444, rmi_driver_dom_show, NULL);

 static ssize_t rmi_driver_product_id_show(struct device *dev,
 					  struct device_attribute *dattr,
 					  char *buf)
 {
 	struct rmi_driver_data *data = dev_get_drvdata(dev);
 	struct f01_data *f01 = dev_get_drvdata(&data->f01_container->dev);

 	return scnprintf(buf, PAGE_SIZE, "%s\n", f01->properties.product_id);
 }

 static DEVICE_ATTR(product_id, 0444, rmi_driver_product_id_show, NULL);

 static ssize_t rmi_driver_firmware_id_show(struct device *dev,
 					   struct device_attribute *dattr,
 					   char *buf)
 {
 	struct rmi_driver_data *data = dev_get_drvdata(dev);
 	struct f01_data *f01 = dev_get_drvdata(&data->f01_container->dev);

 	return scnprintf(buf, PAGE_SIZE, "%d\n", f01->properties.firmware_id);
 }

 static DEVICE_ATTR(firmware_id, 0444, rmi_driver_firmware_id_show, NULL);

 static ssize_t rmi_driver_package_id_show(struct device *dev,
 					  struct device_attribute *dattr,
 					  char *buf)
 {
 	struct rmi_driver_data *data = dev_get_drvdata(dev);
 	struct f01_data *f01 = dev_get_drvdata(&data->f01_container->dev);

 	u32 package_id = f01->properties.package_id;

 	return scnprintf(buf, PAGE_SIZE, "%04x.%04x\n",
 			 package_id & 0xffff, (package_id >> 16) & 0xffff);
 }

 static DEVICE_ATTR(package_id, 0444, rmi_driver_package_id_show, NULL);

 static struct attribute *rmi_f01_attrs[] = {
 	&dev_attr_manufacturer_id.attr,
 	&dev_attr_date_of_manufacture.attr,
 	&dev_attr_product_id.attr,
 	&dev_attr_firmware_id.attr,
 	&dev_attr_package_id.attr,
 	NULL
 };

 static const struct attribute_group rmi_f01_attr_group = {
 	.attrs = rmi_f01_attrs,
 };

 #ifdef CONFIG_OF
 static int rmi_f01_of_probe(struct device *dev,
 				struct rmi_device_platform_data *pdata)
 {
 	int retval;
 	u32 val;

 	retval = rmi_of_property_read_u32(dev,
 			(u32 *)&pdata->power_management.nosleep,
 			"syna,nosleep-mode", 1);
 	if (retval)
 		return retval;

 	retval = rmi_of_property_read_u32(dev, &val,
 			"syna,wakeup-threshold", 1);
 	if (retval)
 		return retval;

 	pdata->power_management.wakeup_threshold = val;

 	retval = rmi_of_property_read_u32(dev, &val,
 			"syna,doze-holdoff-ms", 1);
 	if (retval)
 		return retval;

 	pdata->power_management.doze_holdoff = val * 100;

 	retval = rmi_of_property_read_u32(dev, &val,
 			"syna,doze-interval-ms", 1);
 	if (retval)
 		return retval;

 	pdata->power_management.doze_interval = val / 10;

 	return 0;
 }
 #else
 static inline int rmi_f01_of_probe(struct device *dev,
 					struct rmi_device_platform_data *pdata)
 {
 	return -ENODEV;
 }
 #endif

 static int rmi_f01_probe(struct rmi_function *fn)
 {
 	struct rmi_device *rmi_dev = fn->rmi_dev;
 	struct rmi_driver_data *driver_data = dev_get_drvdata(&rmi_dev->dev);
 	struct rmi_device_platform_data *pdata = rmi_get_platform_data(rmi_dev);
 	struct f01_data *f01;
 	int error;
 	u16 ctrl_base_addr = fn->fd.control_base_addr;
 	u8 device_status;
 	u8 temp;

 	if (fn->dev.of_node) {
 		error = rmi_f01_of_probe(&fn->dev, pdata);
 		if (error)
 			return error;
 	}

 	f01 = devm_kzalloc(&fn->dev, sizeof(struct f01_data), GFP_KERNEL);
 	if (!f01)
 		return -ENOMEM;

 	f01->num_of_irq_regs = driver_data->num_of_irq_regs;

 	/*
 	 * Set the configured bit and (optionally) other important stuff
 	 * in the device control register.
 	 */

 	error = rmi_read(rmi_dev, fn->fd.control_base_addr,
 			 &f01->device_control.ctrl0);
 	if (error) {
 		dev_err(&fn->dev, "Failed to read F01 control: %d\n", error);
 		return error;
 	}

 	switch (pdata->power_management.nosleep) {
 	case RMI_REG_STATE_DEFAULT:
 		break;
 	case RMI_REG_STATE_OFF:
 		f01->device_control.ctrl0 &= ~RMI_F01_CTRL0_NOSLEEP_BIT;
 		break;
 	case RMI_REG_STATE_ON:
 		f01->device_control.ctrl0 |= RMI_F01_CTRL0_NOSLEEP_BIT;
 		break;
 	}

 	/*
 	 * Sleep mode might be set as a hangover from a system crash or
 	 * reboot without power cycle.  If so, clear it so the sensor
 	 * is certain to function.
 	 */
 	if ((f01->device_control.ctrl0 & RMI_F01_CTRL0_SLEEP_MODE_MASK) !=
 			RMI_SLEEP_MODE_NORMAL) {
 		dev_warn(&fn->dev,
 			 "WARNING: Non-zero sleep mode found. Clearing...\n");
 		f01->device_control.ctrl0 &= ~RMI_F01_CTRL0_SLEEP_MODE_MASK;
 	}

 	f01->device_control.ctrl0 |= RMI_F01_CTRL0_CONFIGURED_BIT;

 	error = rmi_write(rmi_dev, fn->fd.control_base_addr,
 			  f01->device_control.ctrl0);
 	if (error) {
 		dev_err(&fn->dev, "Failed to write F01 control: %d\n", error);
 		return error;
 	}

 	/* Dummy read in order to clear irqs */
 	error = rmi_read(rmi_dev, fn->fd.data_base_addr + 1, &temp);
 	if (error < 0) {
 		dev_err(&fn->dev, "Failed to read Interrupt Status.\n");
 		return error;
 	}

 	error = rmi_f01_read_properties(rmi_dev, fn->fd.query_base_addr,
 					&f01->properties);
 	if (error < 0) {
 		dev_err(&fn->dev, "Failed to read F01 properties.\n");
 		return error;
 	}

 	dev_info(&fn->dev, "found RMI device, manufacturer: %s, product: %s, fw id: %d\n",
 		 f01->properties.manufacturer_id == 1 ? "Synaptics" : "unknown",
 		 f01->properties.product_id, f01->properties.firmware_id);

 	/* Advance to interrupt control registers, then skip over them. */
 	ctrl_base_addr++;
 	ctrl_base_addr += f01->num_of_irq_regs;

 	/* read control register */
 	if (f01->properties.has_adjustable_doze) {
 		f01->doze_interval_addr = ctrl_base_addr;
 		ctrl_base_addr++;

 		if (pdata->power_management.doze_interval) {
 			f01->device_control.doze_interval =
 				pdata->power_management.doze_interval;
 			error = rmi_write(rmi_dev, f01->doze_interval_addr,
 					  f01->device_control.doze_interval);
 			if (error) {
 				dev_err(&fn->dev,
 					"Failed to configure F01 doze interval register: %d\n",
 					error);
 				return error;
 			}
 		} else {
 			error = rmi_read(rmi_dev, f01->doze_interval_addr,
 					 &f01->device_control.doze_interval);
 			if (error) {
 				dev_err(&fn->dev,
 					"Failed to read F01 doze interval register: %d\n",
 					error);
 				return error;
 			}
 		}

 		f01->wakeup_threshold_addr = ctrl_base_addr;
 		ctrl_base_addr++;

 		if (pdata->power_management.wakeup_threshold) {
 			f01->device_control.wakeup_threshold =
 				pdata->power_management.wakeup_threshold;
 			error = rmi_write(rmi_dev, f01->wakeup_threshold_addr,
 					  f01->device_control.wakeup_threshold);
 			if (error) {
 				dev_err(&fn->dev,
 					"Failed to configure F01 wakeup threshold register: %d\n",
 					error);
 				return error;
 			}
 		} else {
 			error = rmi_read(rmi_dev, f01->wakeup_threshold_addr,
 					 &f01->device_control.wakeup_threshold);
 			if (error < 0) {
 				dev_err(&fn->dev,
 					"Failed to read F01 wakeup threshold register: %d\n",
 					error);
 				return error;
 			}
 		}
 	}

 	if (f01->properties.has_lts)
 		ctrl_base_addr++;

 	if (f01->properties.has_adjustable_doze_holdoff) {
 		f01->doze_holdoff_addr = ctrl_base_addr;
 		ctrl_base_addr++;

 		if (pdata->power_management.doze_holdoff) {
 			f01->device_control.doze_holdoff =
 				pdata->power_management.doze_holdoff;
 			error = rmi_write(rmi_dev, f01->doze_holdoff_addr,
 					  f01->device_control.doze_holdoff);
 			if (error) {
 				dev_err(&fn->dev,
 					"Failed to configure F01 doze holdoff register: %d\n",
 					error);
 				return error;
 			}
 		} else {
 			error = rmi_read(rmi_dev, f01->doze_holdoff_addr,
 					 &f01->device_control.doze_holdoff);
 			if (error) {
 				dev_err(&fn->dev,
 					"Failed to read F01 doze holdoff register: %d\n",
 					error);
 				return error;
 			}
 		}
 	}

 	error = rmi_read(rmi_dev, fn->fd.data_base_addr, &device_status);
 	if (error < 0) {
 		dev_err(&fn->dev,
 			"Failed to read device status: %d\n", error);
 		return error;
 	}

 	if (RMI_F01_STATUS_UNCONFIGURED(device_status)) {
 		dev_err(&fn->dev,
 			"Device was reset during configuration process, status: %#02x!\n",
 			RMI_F01_STATUS_CODE(device_status));
 		return -EINVAL;
 	}

 	dev_set_drvdata(&fn->dev, f01);

 	error = sysfs_create_group(&fn->rmi_dev->dev.kobj, &rmi_f01_attr_group);
 	if (error)
 		dev_warn(&fn->dev, "Failed to create sysfs group: %d\n", error);

 	return 0;
 }

 static void rmi_f01_remove(struct rmi_function *fn)
 {
 	/* Note that the bus device is used, not the F01 device */
 	sysfs_remove_group(&fn->rmi_dev->dev.kobj, &rmi_f01_attr_group);
 }

 static int rmi_f01_config(struct rmi_function *fn)
 {
 	struct f01_data *f01 = dev_get_drvdata(&fn->dev);
 	int error;

 	error = rmi_write(fn->rmi_dev, fn->fd.control_base_addr,
 			  f01->device_control.ctrl0);
 	if (error) {
 		dev_err(&fn->dev,
 			"Failed to write device_control register: %d\n", error);
 		return error;
 	}

 	if (f01->properties.has_adjustable_doze) {
 		error = rmi_write(fn->rmi_dev, f01->doze_interval_addr,
 				  f01->device_control.doze_interval);
 		if (error) {
 			dev_err(&fn->dev,
 				"Failed to write doze interval: %d\n", error);
 			return error;
 		}

 		error = rmi_write_block(fn->rmi_dev,
 					 f01->wakeup_threshold_addr,
 					 &f01->device_control.wakeup_threshold,
 					 sizeof(u8));
 		if (error) {
 			dev_err(&fn->dev,
 				"Failed to write wakeup threshold: %d\n",
 				error);
 			return error;
 		}
 	}

 	if (f01->properties.has_adjustable_doze_holdoff) {
 		error = rmi_write(fn->rmi_dev, f01->doze_holdoff_addr,
 				  f01->device_control.doze_holdoff);
 		if (error) {
 			dev_err(&fn->dev,
 				"Failed to write doze holdoff: %d\n", error);
 			return error;
 		}
 	}

 	return 0;
 }

 static int rmi_f01_suspend(struct rmi_function *fn)
 {
 	struct f01_data *f01 = dev_get_drvdata(&fn->dev);
 	int error;

 	f01->old_nosleep =
 		f01->device_control.ctrl0 & RMI_F01_CTRL0_NOSLEEP_BIT;
 	f01->device_control.ctrl0 &= ~RMI_F01_CTRL0_NOSLEEP_BIT;

 	f01->device_control.ctrl0 &= ~RMI_F01_CTRL0_SLEEP_MODE_MASK;
 	if (device_may_wakeup(fn->rmi_dev->xport->dev))
 		f01->device_control.ctrl0 |= RMI_SLEEP_MODE_RESERVED1;
 	else
 		f01->device_control.ctrl0 |= RMI_SLEEP_MODE_SENSOR_SLEEP;

 	error = rmi_write(fn->rmi_dev, fn->fd.control_base_addr,
 			  f01->device_control.ctrl0);
 	if (error) {
 		dev_err(&fn->dev, "Failed to write sleep mode: %d.\n", error);
 		if (f01->old_nosleep)
 			f01->device_control.ctrl0 |= RMI_F01_CTRL0_NOSLEEP_BIT;
 		f01->device_control.ctrl0 &= ~RMI_F01_CTRL0_SLEEP_MODE_MASK;
 		f01->device_control.ctrl0 |= RMI_SLEEP_MODE_NORMAL;
 		return error;
 	}

 	return 0;
 }

 static int rmi_f01_resume(struct rmi_function *fn)
 {
 	struct f01_data *f01 = dev_get_drvdata(&fn->dev);
 	int error;

 	if (f01->old_nosleep)
 		f01->device_control.ctrl0 |= RMI_F01_CTRL0_NOSLEEP_BIT;

 	f01->device_control.ctrl0 &= ~RMI_F01_CTRL0_SLEEP_MODE_MASK;
 	f01->device_control.ctrl0 |= RMI_SLEEP_MODE_NORMAL;

 	error = rmi_write(fn->rmi_dev, fn->fd.control_base_addr,
 			  f01->device_control.ctrl0);
 	if (error) {
 		dev_err(&fn->dev,
 			"Failed to restore normal operation: %d.\n", error);
 		return error;
 	}

 	return 0;
 }

 static irqreturn_t rmi_f01_attention(int irq, void *ctx)
 {
 	struct rmi_function *fn = ctx;
 	struct rmi_device *rmi_dev = fn->rmi_dev;
 	int error;
 	u8 device_status;

 	error = rmi_read(rmi_dev, fn->fd.data_base_addr, &device_status);
 	if (error) {
 		dev_err(&fn->dev,
 			"Failed to read device status: %d.\n", error);
 		return IRQ_RETVAL(error);
 	}

 	if (RMI_F01_STATUS_BOOTLOADER(device_status))
 		dev_warn(&fn->dev,
 			 "Device in bootloader mode, please update firmware\n");

 	if (RMI_F01_STATUS_UNCONFIGURED(device_status)) {
 		dev_warn(&fn->dev, "Device reset detected.\n");
 		error = rmi_dev->driver->reset_handler(rmi_dev);
 		if (error) {
 			dev_err(&fn->dev, "Device reset failed: %d\n", error);
 			return IRQ_RETVAL(error);
 		}
 	}

 	return IRQ_HANDLED;
 }

 struct rmi_function_handler rmi_f01_handler = {
 	.driver = {
 		.name	= "rmi4_f01",
 		/*
 		 * Do not allow user unbinding F01 as it is critical
 		 * function.
 		 */
 		.suppress_bind_attrs = true,
 	},
 	.func		= 0x01,
 	.probe		= rmi_f01_probe,
 	.remove		= rmi_f01_remove,
 	.config		= rmi_f01_config,
 	.attention	= rmi_f01_attention,
 	.suspend	= rmi_f01_suspend,
 	.resume		= rmi_f01_resume,
 };
	// SPDX-License-Identifier: GPL-2.0-only
	/*
	* Copyright (c) 2011-2016 Synaptics Incorporated
	* Copyright (c) 2011 Unixphere
	*/

	#include <linux/kernel.h>
	#include <linux/rmi.h>
	#include <linux/slab.h>
	#include <linux/uaccess.h>
	#include <linux/of.h>
	#include <asm/unaligned.h>
	#include "rmi_driver.h"

	#define RMI_PRODUCT_ID_LENGTH 10
	#define RMI_PRODUCT_INFO_LENGTH 2

	#define RMI_DATE_CODE_LENGTH 3

	#define PRODUCT_ID_OFFSET 0x10
	#define PRODUCT_INFO_OFFSET 0x1E


	/* Force a firmware reset of the sensor */
	#define RMI_F01_CMD_DEVICE_RESET 1

	/* Various F01_RMI_QueryX bits */

	#define RMI_F01_QRY1_CUSTOM_MAP BIT(0)
	#define RMI_F01_QRY1_NON_COMPLIANT BIT(1)
	#define RMI_F01_QRY1_HAS_LTS BIT(2)
	#define RMI_F01_QRY1_HAS_SENSOR_ID BIT(3)
	#define RMI_F01_QRY1_HAS_CHARGER_INP BIT(4)
	#define RMI_F01_QRY1_HAS_ADJ_DOZE BIT(5)
	#define RMI_F01_QRY1_HAS_ADJ_DOZE_HOFF BIT(6)
	#define RMI_F01_QRY1_HAS_QUERY42 BIT(7)

	#define RMI_F01_QRY5_YEAR_MASK 0x1f
	#define RMI_F01_QRY6_MONTH_MASK 0x0f
	#define RMI_F01_QRY7_DAY_MASK 0x1f

	#define RMI_F01_QRY2_PRODINFO_MASK 0x7f

	#define RMI_F01_BASIC_QUERY_LEN 21 /* From Query 00 through 20 */

	struct f01_basic_properties {
	u8 manufacturer_id;
	bool has_lts;
	bool has_adjustable_doze;
	bool has_adjustable_doze_holdoff;
	char dom[11]; /* YYYY/MM/DD + '\0' */
	u8 product_id[RMI_PRODUCT_ID_LENGTH + 1];
	u16 productinfo;
	u32 firmware_id;
	u32 package_id;
	};

	/* F01 device status bits */

	/* Most recent device status event */
	#define RMI_F01_STATUS_CODE(status) ((status) & 0x0f)
	/* The device has lost its configuration for some reason. */
	#define RMI_F01_STATUS_UNCONFIGURED(status) (!!((status) & 0x80))
	/* The device is in bootloader mode */
	#define RMI_F01_STATUS_BOOTLOADER(status) ((status) & 0x40)

	/* Control register bits */

	/*
	* Sleep mode controls power management on the device and affects all
	* functions of the device.
	*/
	#define RMI_F01_CTRL0_SLEEP_MODE_MASK 0x03

	#define RMI_SLEEP_MODE_NORMAL 0x00
	#define RMI_SLEEP_MODE_SENSOR_SLEEP 0x01
	#define RMI_SLEEP_MODE_RESERVED0 0x02
	#define RMI_SLEEP_MODE_RESERVED1 0x03

	/*
	* This bit disables whatever sleep mode may be selected by the sleep_mode
	* field and forces the device to run at full power without sleeping.
	*/
	#define RMI_F01_CTRL0_NOSLEEP_BIT BIT(2)

	/*
	* When this bit is set, the touch controller employs a noise-filtering
	* algorithm designed for use with a connected battery charger.
	*/
	#define RMI_F01_CTRL0_CHARGER_BIT BIT(5)

	/*
	* Sets the report rate for the device. The effect of this setting is
	* highly product dependent. Check the spec sheet for your particular
	* touch sensor.
	*/
	#define RMI_F01_CTRL0_REPORTRATE_BIT BIT(6)

	/*
	* Written by the host as an indicator that the device has been
	* successfully configured.
	*/
	#define RMI_F01_CTRL0_CONFIGURED_BIT BIT(7)

	/**
	* struct f01_device_control - controls basic sensor functions
	*
	* @ctrl0: see the bit definitions above.
	* @doze_interval: controls the interval between checks for finger presence
	* when the touch sensor is in doze mode, in units of 10ms.
	* @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.
	*/
	struct f01_device_control {
	u8 ctrl0;
	u8 doze_interval;
	u8 wakeup_threshold;
	u8 doze_holdoff;
	};

	struct f01_data {
	struct f01_basic_properties properties;
	struct f01_device_control device_control;

	u16 doze_interval_addr;
	u16 wakeup_threshold_addr;
	u16 doze_holdoff_addr;

	bool suspended;
	bool old_nosleep;

	unsigned int num_of_irq_regs;
	};

	static int rmi_f01_read_properties(struct rmi_device *rmi_dev,
	u16 query_base_addr,
	struct f01_basic_properties *props)
	{
	u8 queries[RMI_F01_BASIC_QUERY_LEN];
	int ret;
	int query_offset = query_base_addr;
	bool has_ds4_queries = false;
	bool has_query42 = false;
	bool has_sensor_id = false;
	bool has_package_id_query = false;
	bool has_build_id_query = false;
	u16 prod_info_addr;
	u8 ds4_query_len;

	ret = rmi_read_block(rmi_dev, query_offset,
	queries, RMI_F01_BASIC_QUERY_LEN);
	if (ret) {
	dev_err(&rmi_dev->dev,
	"Failed to read device query registers: %d\n", ret);
	return ret;
	}

	prod_info_addr = query_offset + 17;
	query_offset += RMI_F01_BASIC_QUERY_LEN;

	/* Now parse what we got */
	props->manufacturer_id = queries[0];

	props->has_lts = queries[1] & RMI_F01_QRY1_HAS_LTS;
	props->has_adjustable_doze =
	queries[1] & RMI_F01_QRY1_HAS_ADJ_DOZE;
	props->has_adjustable_doze_holdoff =
	queries[1] & RMI_F01_QRY1_HAS_ADJ_DOZE_HOFF;
	has_query42 = queries[1] & RMI_F01_QRY1_HAS_QUERY42;
	has_sensor_id = queries[1] & RMI_F01_QRY1_HAS_SENSOR_ID;

	snprintf(props->dom, sizeof(props->dom), "20%02d/%02d/%02d",
	queries[5] & RMI_F01_QRY5_YEAR_MASK,
	queries[6] & RMI_F01_QRY6_MONTH_MASK,
	queries[7] & RMI_F01_QRY7_DAY_MASK);

	memcpy(props->product_id, &queries[11],
	RMI_PRODUCT_ID_LENGTH);
	props->product_id[RMI_PRODUCT_ID_LENGTH] = '\0';

	props->productinfo =
	((queries[2] & RMI_F01_QRY2_PRODINFO_MASK) << 7) \|
	(queries[3] & RMI_F01_QRY2_PRODINFO_MASK);

	if (has_sensor_id)
	query_offset++;

	if (has_query42) {
	ret = rmi_read(rmi_dev, query_offset, queries);
	if (ret) {
	dev_err(&rmi_dev->dev,
	"Failed to read query 42 register: %d\n", ret);
	return ret;
	}

	has_ds4_queries = !!(queries[0] & BIT(0));
	query_offset++;
	}

	if (has_ds4_queries) {
	ret = rmi_read(rmi_dev, query_offset, &ds4_query_len);
	if (ret) {
	dev_err(&rmi_dev->dev,
	"Failed to read DS4 queries length: %d\n", ret);
	return ret;
	}
	query_offset++;

	if (ds4_query_len > 0) {
	ret = rmi_read(rmi_dev, query_offset, queries);
	if (ret) {
	dev_err(&rmi_dev->dev,
	"Failed to read DS4 queries: %d\n",
	ret);
	return ret;
	}

	has_package_id_query = !!(queries[0] & BIT(0));
	has_build_id_query = !!(queries[0] & BIT(1));
	}

	if (has_package_id_query) {
	ret = rmi_read_block(rmi_dev, prod_info_addr,
	queries, sizeof(__le64));
	if (ret) {
	dev_err(&rmi_dev->dev,
	"Failed to read package info: %d\n",
	ret);
	return ret;
	}

	props->package_id = get_unaligned_le64(queries);
	prod_info_addr++;
	}

	if (has_build_id_query) {
	ret = rmi_read_block(rmi_dev, prod_info_addr, queries,
	3);
	if (ret) {
	dev_err(&rmi_dev->dev,
	"Failed to read product info: %d\n",
	ret);
	return ret;
	}

	props->firmware_id = queries[1] << 8 \| queries[0];
	props->firmware_id += queries[2] * 65536;
	}
	}

	return 0;
	}

	const char rmi_f01_get_product_ID(struct rmi_function fn)
	{
	struct f01_data *f01 = dev_get_drvdata(&fn->dev);

	return f01->properties.product_id;
	}

	static ssize_t rmi_driver_manufacturer_id_show(struct device *dev,
	struct device_attribute *dattr,
	char *buf)
	{
	struct rmi_driver_data *data = dev_get_drvdata(dev);
	struct f01_data *f01 = dev_get_drvdata(&data->f01_container->dev);

	return scnprintf(buf, PAGE_SIZE, "%d\n",
	f01->properties.manufacturer_id);
	}

	static DEVICE_ATTR(manufacturer_id, 0444,
	rmi_driver_manufacturer_id_show, NULL);

	static ssize_t rmi_driver_dom_show(struct device *dev,
	struct device_attribute dattr, char buf)
	{
	struct rmi_driver_data *data = dev_get_drvdata(dev);
	struct f01_data *f01 = dev_get_drvdata(&data->f01_container->dev);

	return scnprintf(buf, PAGE_SIZE, "%s\n", f01->properties.dom);
	}

	static DEVICE_ATTR(date_of_manufacture, 0444, rmi_driver_dom_show, NULL);

	static ssize_t rmi_driver_product_id_show(struct device *dev,
	struct device_attribute *dattr,
	char *buf)
	{
	struct rmi_driver_data *data = dev_get_drvdata(dev);
	struct f01_data *f01 = dev_get_drvdata(&data->f01_container->dev);

	return scnprintf(buf, PAGE_SIZE, "%s\n", f01->properties.product_id);
	}

	static DEVICE_ATTR(product_id, 0444, rmi_driver_product_id_show, NULL);

	static ssize_t rmi_driver_firmware_id_show(struct device *dev,
	struct device_attribute *dattr,
	char *buf)
	{
	struct rmi_driver_data *data = dev_get_drvdata(dev);
	struct f01_data *f01 = dev_get_drvdata(&data->f01_container->dev);

	return scnprintf(buf, PAGE_SIZE, "%d\n", f01->properties.firmware_id);
	}

	static DEVICE_ATTR(firmware_id, 0444, rmi_driver_firmware_id_show, NULL);

	static ssize_t rmi_driver_package_id_show(struct device *dev,
	struct device_attribute *dattr,
	char *buf)
	{
	struct rmi_driver_data *data = dev_get_drvdata(dev);
	struct f01_data *f01 = dev_get_drvdata(&data->f01_container->dev);

	u32 package_id = f01->properties.package_id;

	return scnprintf(buf, PAGE_SIZE, "%04x.%04x\n",
	package_id & 0xffff, (package_id >> 16) & 0xffff);
	}

	static DEVICE_ATTR(package_id, 0444, rmi_driver_package_id_show, NULL);

	static struct attribute *rmi_f01_attrs[] = {
	&dev_attr_manufacturer_id.attr,
	&dev_attr_date_of_manufacture.attr,
	&dev_attr_product_id.attr,
	&dev_attr_firmware_id.attr,
	&dev_attr_package_id.attr,
	NULL
	};

	static const struct attribute_group rmi_f01_attr_group = {
	.attrs = rmi_f01_attrs,
	};

	#ifdef CONFIG_OF
	static int rmi_f01_of_probe(struct device *dev,
	struct rmi_device_platform_data *pdata)
	{
	int retval;
	u32 val;

	retval = rmi_of_property_read_u32(dev,
	(u32 *)&pdata->power_management.nosleep,
	"syna,nosleep-mode", 1);
	if (retval)
	return retval;

	retval = rmi_of_property_read_u32(dev, &val,
	"syna,wakeup-threshold", 1);
	if (retval)
	return retval;

	pdata->power_management.wakeup_threshold = val;

	retval = rmi_of_property_read_u32(dev, &val,
	"syna,doze-holdoff-ms", 1);
	if (retval)
	return retval;

	pdata->power_management.doze_holdoff = val * 100;

	retval = rmi_of_property_read_u32(dev, &val,
	"syna,doze-interval-ms", 1);
	if (retval)
	return retval;

	pdata->power_management.doze_interval = val / 10;

	return 0;
	}
	#else
	static inline int rmi_f01_of_probe(struct device *dev,
	struct rmi_device_platform_data *pdata)
	{
	return -ENODEV;
	}
	#endif

	static int rmi_f01_probe(struct rmi_function *fn)
	{
	struct rmi_device *rmi_dev = fn->rmi_dev;
	struct rmi_driver_data *driver_data = dev_get_drvdata(&rmi_dev->dev);
	struct rmi_device_platform_data *pdata = rmi_get_platform_data(rmi_dev);
	struct f01_data *f01;
	int error;
	u16 ctrl_base_addr = fn->fd.control_base_addr;
	u8 device_status;
	u8 temp;

	if (fn->dev.of_node) {
	error = rmi_f01_of_probe(&fn->dev, pdata);
	if (error)
	return error;
	}

	f01 = devm_kzalloc(&fn->dev, sizeof(struct f01_data), GFP_KERNEL);
	if (!f01)
	return -ENOMEM;

	f01->num_of_irq_regs = driver_data->num_of_irq_regs;

	/*
	* Set the configured bit and (optionally) other important stuff
	* in the device control register.
	*/

	error = rmi_read(rmi_dev, fn->fd.control_base_addr,
	&f01->device_control.ctrl0);
	if (error) {
	dev_err(&fn->dev, "Failed to read F01 control: %d\n", error);
	return error;
	}

	switch (pdata->power_management.nosleep) {
	case RMI_REG_STATE_DEFAULT:
	break;
	case RMI_REG_STATE_OFF:
	f01->device_control.ctrl0 &= ~RMI_F01_CTRL0_NOSLEEP_BIT;
	break;
	case RMI_REG_STATE_ON:
	f01->device_control.ctrl0 \|= RMI_F01_CTRL0_NOSLEEP_BIT;
	break;
	}

	/*
	* Sleep mode might be set as a hangover from a system crash or
	* reboot without power cycle. If so, clear it so the sensor
	* is certain to function.
	*/
	if ((f01->device_control.ctrl0 & RMI_F01_CTRL0_SLEEP_MODE_MASK) !=
	RMI_SLEEP_MODE_NORMAL) {
	dev_warn(&fn->dev,
	"WARNING: Non-zero sleep mode found. Clearing...\n");
	f01->device_control.ctrl0 &= ~RMI_F01_CTRL0_SLEEP_MODE_MASK;
	}

	f01->device_control.ctrl0 \|= RMI_F01_CTRL0_CONFIGURED_BIT;

	error = rmi_write(rmi_dev, fn->fd.control_base_addr,
	f01->device_control.ctrl0);
	if (error) {
	dev_err(&fn->dev, "Failed to write F01 control: %d\n", error);
	return error;
	}

	/* Dummy read in order to clear irqs */
	error = rmi_read(rmi_dev, fn->fd.data_base_addr + 1, &temp);
	if (error < 0) {
	dev_err(&fn->dev, "Failed to read Interrupt Status.\n");
	return error;
	}

	error = rmi_f01_read_properties(rmi_dev, fn->fd.query_base_addr,
	&f01->properties);
	if (error < 0) {
	dev_err(&fn->dev, "Failed to read F01 properties.\n");
	return error;
	}

	dev_info(&fn->dev, "found RMI device, manufacturer: %s, product: %s, fw id: %d\n",
	f01->properties.manufacturer_id == 1 ? "Synaptics" : "unknown",
	f01->properties.product_id, f01->properties.firmware_id);

	/* Advance to interrupt control registers, then skip over them. */
	ctrl_base_addr++;
	ctrl_base_addr += f01->num_of_irq_regs;

	/* read control register */
	if (f01->properties.has_adjustable_doze) {
	f01->doze_interval_addr = ctrl_base_addr;
	ctrl_base_addr++;

	if (pdata->power_management.doze_interval) {
	f01->device_control.doze_interval =
	pdata->power_management.doze_interval;
	error = rmi_write(rmi_dev, f01->doze_interval_addr,
	f01->device_control.doze_interval);
	if (error) {
	dev_err(&fn->dev,
	"Failed to configure F01 doze interval register: %d\n",
	error);
	return error;
	}
	} else {
	error = rmi_read(rmi_dev, f01->doze_interval_addr,
	&f01->device_control.doze_interval);
	if (error) {
	dev_err(&fn->dev,
	"Failed to read F01 doze interval register: %d\n",
	error);
	return error;
	}
	}

	f01->wakeup_threshold_addr = ctrl_base_addr;
	ctrl_base_addr++;

	if (pdata->power_management.wakeup_threshold) {
	f01->device_control.wakeup_threshold =
	pdata->power_management.wakeup_threshold;
	error = rmi_write(rmi_dev, f01->wakeup_threshold_addr,
	f01->device_control.wakeup_threshold);
	if (error) {
	dev_err(&fn->dev,
	"Failed to configure F01 wakeup threshold register: %d\n",
	error);
	return error;
	}
	} else {
	error = rmi_read(rmi_dev, f01->wakeup_threshold_addr,
	&f01->device_control.wakeup_threshold);
	if (error < 0) {
	dev_err(&fn->dev,
	"Failed to read F01 wakeup threshold register: %d\n",
	error);
	return error;
	}
	}
	}

	if (f01->properties.has_lts)
	ctrl_base_addr++;

	if (f01->properties.has_adjustable_doze_holdoff) {
	f01->doze_holdoff_addr = ctrl_base_addr;
	ctrl_base_addr++;

	if (pdata->power_management.doze_holdoff) {
	f01->device_control.doze_holdoff =
	pdata->power_management.doze_holdoff;
	error = rmi_write(rmi_dev, f01->doze_holdoff_addr,
	f01->device_control.doze_holdoff);
	if (error) {
	dev_err(&fn->dev,
	"Failed to configure F01 doze holdoff register: %d\n",
	error);
	return error;
	}
	} else {
	error = rmi_read(rmi_dev, f01->doze_holdoff_addr,
	&f01->device_control.doze_holdoff);
	if (error) {
	dev_err(&fn->dev,
	"Failed to read F01 doze holdoff register: %d\n",
	error);
	return error;
	}
	}
	}

	error = rmi_read(rmi_dev, fn->fd.data_base_addr, &device_status);
	if (error < 0) {
	dev_err(&fn->dev,
	"Failed to read device status: %d\n", error);
	return error;
	}

	if (RMI_F01_STATUS_UNCONFIGURED(device_status)) {
	dev_err(&fn->dev,
	"Device was reset during configuration process, status: %#02x!\n",
	RMI_F01_STATUS_CODE(device_status));
	return -EINVAL;
	}

	dev_set_drvdata(&fn->dev, f01);

	error = sysfs_create_group(&fn->rmi_dev->dev.kobj, &rmi_f01_attr_group);
	if (error)
	dev_warn(&fn->dev, "Failed to create sysfs group: %d\n", error);

	return 0;
	}

	static void rmi_f01_remove(struct rmi_function *fn)
	{
	/* Note that the bus device is used, not the F01 device */
	sysfs_remove_group(&fn->rmi_dev->dev.kobj, &rmi_f01_attr_group);
	}

	static int rmi_f01_config(struct rmi_function *fn)
	{
	struct f01_data *f01 = dev_get_drvdata(&fn->dev);
	int error;

	error = rmi_write(fn->rmi_dev, fn->fd.control_base_addr,
	f01->device_control.ctrl0);
	if (error) {
	dev_err(&fn->dev,
	"Failed to write device_control register: %d\n", error);
	return error;
	}

	if (f01->properties.has_adjustable_doze) {
	error = rmi_write(fn->rmi_dev, f01->doze_interval_addr,
	f01->device_control.doze_interval);
	if (error) {
	dev_err(&fn->dev,
	"Failed to write doze interval: %d\n", error);
	return error;
	}

	error = rmi_write_block(fn->rmi_dev,
	f01->wakeup_threshold_addr,
	&f01->device_control.wakeup_threshold,
	sizeof(u8));
	if (error) {
	dev_err(&fn->dev,
	"Failed to write wakeup threshold: %d\n",
	error);
	return error;
	}
	}

	if (f01->properties.has_adjustable_doze_holdoff) {
	error = rmi_write(fn->rmi_dev, f01->doze_holdoff_addr,
	f01->device_control.doze_holdoff);
	if (error) {
	dev_err(&fn->dev,
	"Failed to write doze holdoff: %d\n", error);
	return error;
	}
	}

	return 0;
	}

	static int rmi_f01_suspend(struct rmi_function *fn)
	{
	struct f01_data *f01 = dev_get_drvdata(&fn->dev);
	int error;

	f01->old_nosleep =
	f01->device_control.ctrl0 & RMI_F01_CTRL0_NOSLEEP_BIT;
	f01->device_control.ctrl0 &= ~RMI_F01_CTRL0_NOSLEEP_BIT;

	f01->device_control.ctrl0 &= ~RMI_F01_CTRL0_SLEEP_MODE_MASK;
	if (device_may_wakeup(fn->rmi_dev->xport->dev))
	f01->device_control.ctrl0 \|= RMI_SLEEP_MODE_RESERVED1;
	else
	f01->device_control.ctrl0 \|= RMI_SLEEP_MODE_SENSOR_SLEEP;

	error = rmi_write(fn->rmi_dev, fn->fd.control_base_addr,
	f01->device_control.ctrl0);
	if (error) {
	dev_err(&fn->dev, "Failed to write sleep mode: %d.\n", error);
	if (f01->old_nosleep)
	f01->device_control.ctrl0 \|= RMI_F01_CTRL0_NOSLEEP_BIT;
	f01->device_control.ctrl0 &= ~RMI_F01_CTRL0_SLEEP_MODE_MASK;
	f01->device_control.ctrl0 \|= RMI_SLEEP_MODE_NORMAL;
	return error;
	}

	return 0;
	}

	static int rmi_f01_resume(struct rmi_function *fn)
	{
	struct f01_data *f01 = dev_get_drvdata(&fn->dev);
	int error;

	if (f01->old_nosleep)
	f01->device_control.ctrl0 \|= RMI_F01_CTRL0_NOSLEEP_BIT;

	f01->device_control.ctrl0 &= ~RMI_F01_CTRL0_SLEEP_MODE_MASK;
	f01->device_control.ctrl0 \|= RMI_SLEEP_MODE_NORMAL;

	error = rmi_write(fn->rmi_dev, fn->fd.control_base_addr,
	f01->device_control.ctrl0);
	if (error) {
	dev_err(&fn->dev,
	"Failed to restore normal operation: %d.\n", error);
	return error;
	}

	return 0;
	}

	static irqreturn_t rmi_f01_attention(int irq, void *ctx)
	{
	struct rmi_function *fn = ctx;
	struct rmi_device *rmi_dev = fn->rmi_dev;
	int error;
	u8 device_status;

	error = rmi_read(rmi_dev, fn->fd.data_base_addr, &device_status);
	if (error) {
	dev_err(&fn->dev,
	"Failed to read device status: %d.\n", error);
	return IRQ_RETVAL(error);
	}

	if (RMI_F01_STATUS_BOOTLOADER(device_status))
	dev_warn(&fn->dev,
	"Device in bootloader mode, please update firmware\n");

	if (RMI_F01_STATUS_UNCONFIGURED(device_status)) {
	dev_warn(&fn->dev, "Device reset detected.\n");
	error = rmi_dev->driver->reset_handler(rmi_dev);
	if (error) {
	dev_err(&fn->dev, "Device reset failed: %d\n", error);
	return IRQ_RETVAL(error);
	}
	}

	return IRQ_HANDLED;
	}

	struct rmi_function_handler rmi_f01_handler = {
	.driver = {
	.name = "rmi4_f01",
	/*
	* Do not allow user unbinding F01 as it is critical
	* function.
	*/
	.suppress_bind_attrs = true,
	},
	.func = 0x01,
	.probe = rmi_f01_probe,
	.remove = rmi_f01_remove,
	.config = rmi_f01_config,
	.attention = rmi_f01_attention,
	.suspend = rmi_f01_suspend,
	.resume = rmi_f01_resume,
	};