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/* SPDX-License-Identifier: GPL-2.0-only */
/*
* Remote Controller core header
*
* Copyright (C) 2009-2010 by Mauro Carvalho Chehab
*/
#ifndef _RC_CORE
#define _RC_CORE
#include <linux/spinlock.h>
#include <linux/cdev.h>
#include <linux/kfifo.h>
#include <linux/time.h>
#include <linux/timer.h>
#include <media/rc-map.h>
/**
* enum rc_driver_type - type of the RC driver.
*
* @RC_DRIVER_SCANCODE: Driver or hardware generates a scancode.
* @RC_DRIVER_IR_RAW: Driver or hardware generates pulse/space sequences.
* It needs a Infra-Red pulse/space decoder
* @RC_DRIVER_IR_RAW_TX: Device transmitter only,
* driver requires pulse/space data sequence.
*/
enum rc_driver_type {
RC_DRIVER_SCANCODE = 0,
RC_DRIVER_IR_RAW,
RC_DRIVER_IR_RAW_TX,
};
/**
* struct rc_scancode_filter - Filter scan codes.
* @data: Scancode data to match.
* @mask: Mask of bits of scancode to compare.
*/
struct rc_scancode_filter {
u32 data;
u32 mask;
};
/**
* enum rc_filter_type - Filter type constants.
* @RC_FILTER_NORMAL: Filter for normal operation.
* @RC_FILTER_WAKEUP: Filter for waking from suspend.
* @RC_FILTER_MAX: Number of filter types.
*/
enum rc_filter_type {
RC_FILTER_NORMAL = 0,
RC_FILTER_WAKEUP,
RC_FILTER_MAX
};
/**
* struct lirc_fh - represents an open lirc file
* @list: list of open file handles
* @rc: rcdev for this lirc chardev
* @carrier_low: when setting the carrier range, first the low end must be
* set with an ioctl and then the high end with another ioctl
* @send_timeout_reports: report timeouts in lirc raw IR.
* @rawir: queue for incoming raw IR
* @scancodes: queue for incoming decoded scancodes
* @wait_poll: poll struct for lirc device
* @send_mode: lirc mode for sending, either LIRC_MODE_SCANCODE or
* LIRC_MODE_PULSE
* @rec_mode: lirc mode for receiving, either LIRC_MODE_SCANCODE or
* LIRC_MODE_MODE2
*/
struct lirc_fh {
struct list_head list;
struct rc_dev *rc;
int carrier_low;
bool send_timeout_reports;
DECLARE_KFIFO_PTR(rawir, unsigned int);
DECLARE_KFIFO_PTR(scancodes, struct lirc_scancode);
wait_queue_head_t wait_poll;
u8 send_mode;
u8 rec_mode;
};
/**
* struct rc_dev - represents a remote control device
* @dev: driver model's view of this device
* @managed_alloc: devm_rc_allocate_device was used to create rc_dev
* @sysfs_groups: sysfs attribute groups
* @device_name: name of the rc child device
* @input_phys: physical path to the input child device
* @input_id: id of the input child device (struct input_id)
* @driver_name: name of the hardware driver which registered this device
* @map_name: name of the default keymap
* @rc_map: current scan/key table
* @lock: used to ensure we've filled in all protocol details before
* anyone can call show_protocols or store_protocols
* @minor: unique minor remote control device number
* @raw: additional data for raw pulse/space devices
* @input_dev: the input child device used to communicate events to userspace
* @driver_type: specifies if protocol decoding is done in hardware or software
* @idle: used to keep track of RX state
* @encode_wakeup: wakeup filtering uses IR encode API, therefore the allowed
* wakeup protocols is the set of all raw encoders
* @allowed_protocols: bitmask with the supported RC_PROTO_BIT_* protocols
* @enabled_protocols: bitmask with the enabled RC_PROTO_BIT_* protocols
* @allowed_wakeup_protocols: bitmask with the supported RC_PROTO_BIT_* wakeup
* protocols
* @wakeup_protocol: the enabled RC_PROTO_* wakeup protocol or
* RC_PROTO_UNKNOWN if disabled.
* @scancode_filter: scancode filter
* @scancode_wakeup_filter: scancode wakeup filters
* @scancode_mask: some hardware decoders are not capable of providing the full
* scancode to the application. As this is a hardware limit, we can't do
* anything with it. Yet, as the same keycode table can be used with other
* devices, a mask is provided to allow its usage. Drivers should generally
* leave this field in blank
* @users: number of current users of the device
* @priv: driver-specific data
* @keylock: protects the remaining members of the struct
* @keypressed: whether a key is currently pressed
* @keyup_jiffies: time (in jiffies) when the current keypress should be released
* @timer_keyup: timer for releasing a keypress
* @timer_repeat: timer for autorepeat events. This is needed for CEC, which
* has non-standard repeats.
* @last_keycode: keycode of last keypress
* @last_protocol: protocol of last keypress
* @last_scancode: scancode of last keypress
* @last_toggle: toggle value of last command
* @timeout: optional time after which device stops sending data
* @min_timeout: minimum timeout supported by device
* @max_timeout: maximum timeout supported by device
* @rx_resolution : resolution (in us) of input sampler
* @tx_resolution: resolution (in us) of output sampler
* @lirc_dev: lirc device
* @lirc_cdev: lirc char cdev
* @gap_start: time when gap starts
* @gap_duration: duration of initial gap
* @gap: true if we're in a gap
* @lirc_fh_lock: protects lirc_fh list
* @lirc_fh: list of open files
* @registered: set to true by rc_register_device(), false by
* rc_unregister_device
* @change_protocol: allow changing the protocol used on hardware decoders
* @open: callback to allow drivers to enable polling/irq when IR input device
* is opened.
* @close: callback to allow drivers to disable polling/irq when IR input device
* is opened.
* @s_tx_mask: set transmitter mask (for devices with multiple tx outputs)
* @s_tx_carrier: set transmit carrier frequency
* @s_tx_duty_cycle: set transmit duty cycle (0% - 100%)
* @s_rx_carrier_range: inform driver about carrier it is expected to handle
* @tx_ir: transmit IR
* @s_idle: enable/disable hardware idle mode, upon which,
* device doesn't interrupt host until it sees IR pulses
* @s_learning_mode: enable wide band receiver used for learning
* @s_carrier_report: enable carrier reports
* @s_filter: set the scancode filter
* @s_wakeup_filter: set the wakeup scancode filter. If the mask is zero
* then wakeup should be disabled. wakeup_protocol will be set to
* a valid protocol if mask is nonzero.
* @s_timeout: set hardware timeout in us
*/
struct rc_dev {
struct device dev;
bool managed_alloc;
const struct attribute_group *sysfs_groups[5];
const char *device_name;
const char *input_phys;
struct input_id input_id;
const char *driver_name;
const char *map_name;
struct rc_map rc_map;
struct mutex lock;
unsigned int minor;
struct ir_raw_event_ctrl *raw;
struct input_dev *input_dev;
enum rc_driver_type driver_type;
bool idle;
bool encode_wakeup;
u64 allowed_protocols;
u64 enabled_protocols;
u64 allowed_wakeup_protocols;
enum rc_proto wakeup_protocol;
struct rc_scancode_filter scancode_filter;
struct rc_scancode_filter scancode_wakeup_filter;
u32 scancode_mask;
u32 users;
void *priv;
spinlock_t keylock;
bool keypressed;
unsigned long keyup_jiffies;
struct timer_list timer_keyup;
struct timer_list timer_repeat;
u32 last_keycode;
enum rc_proto last_protocol;
u64 last_scancode;
u8 last_toggle;
u32 timeout;
u32 min_timeout;
u32 max_timeout;
u32 rx_resolution;
u32 tx_resolution;
#ifdef CONFIG_LIRC
struct device lirc_dev;
struct cdev lirc_cdev;
ktime_t gap_start;
u64 gap_duration;
bool gap;
spinlock_t lirc_fh_lock;
struct list_head lirc_fh;
#endif
bool registered;
int (*change_protocol)(struct rc_dev *dev, u64 *rc_proto);
int (*open)(struct rc_dev *dev);
void (*close)(struct rc_dev *dev);
int (*s_tx_mask)(struct rc_dev *dev, u32 mask);
int (*s_tx_carrier)(struct rc_dev *dev, u32 carrier);
int (*s_tx_duty_cycle)(struct rc_dev *dev, u32 duty_cycle);
int (*s_rx_carrier_range)(struct rc_dev *dev, u32 min, u32 max);
int (*tx_ir)(struct rc_dev *dev, unsigned *txbuf, unsigned n);
void (*s_idle)(struct rc_dev *dev, bool enable);
int (*s_learning_mode)(struct rc_dev *dev, int enable);
int (*s_carrier_report) (struct rc_dev *dev, int enable);
int (*s_filter)(struct rc_dev *dev,
struct rc_scancode_filter *filter);
int (*s_wakeup_filter)(struct rc_dev *dev,
struct rc_scancode_filter *filter);
int (*s_timeout)(struct rc_dev *dev,
unsigned int timeout);
};
#define to_rc_dev(d) container_of(d, struct rc_dev, dev)
/*
* From rc-main.c
* Those functions can be used on any type of Remote Controller. They
* basically creates an input_dev and properly reports the device as a
* Remote Controller, at sys/class/rc.
*/
/**
* rc_allocate_device - Allocates a RC device
*
* @rc_driver_type: specifies the type of the RC output to be allocated
* returns a pointer to struct rc_dev.
*/
struct rc_dev *rc_allocate_device(enum rc_driver_type);
/**
* devm_rc_allocate_device - Managed RC device allocation
*
* @dev: pointer to struct device
* @rc_driver_type: specifies the type of the RC output to be allocated
* returns a pointer to struct rc_dev.
*/
struct rc_dev *devm_rc_allocate_device(struct device *dev, enum rc_driver_type);
/**
* rc_free_device - Frees a RC device
*
* @dev: pointer to struct rc_dev.
*/
void rc_free_device(struct rc_dev *dev);
/**
* rc_register_device - Registers a RC device
*
* @dev: pointer to struct rc_dev.
*/
int rc_register_device(struct rc_dev *dev);
/**
* devm_rc_register_device - Manageded registering of a RC device
*
* @parent: pointer to struct device.
* @dev: pointer to struct rc_dev.
*/
int devm_rc_register_device(struct device *parent, struct rc_dev *dev);
/**
* rc_unregister_device - Unregisters a RC device
*
* @dev: pointer to struct rc_dev.
*/
void rc_unregister_device(struct rc_dev *dev);
void rc_repeat(struct rc_dev *dev);
void rc_keydown(struct rc_dev *dev, enum rc_proto protocol, u64 scancode,
u8 toggle);
void rc_keydown_notimeout(struct rc_dev *dev, enum rc_proto protocol,
u64 scancode, u8 toggle);
void rc_keyup(struct rc_dev *dev);
u32 rc_g_keycode_from_table(struct rc_dev *dev, u64 scancode);
/*
* From rc-raw.c
* The Raw interface is specific to InfraRed. It may be a good idea to
* split it later into a separate header.
*/
struct ir_raw_event {
union {
u32 duration;
u32 carrier;
};
u8 duty_cycle;
unsigned pulse:1;
unsigned reset:1;
unsigned timeout:1;
unsigned carrier_report:1;
};
#define US_TO_NS(usec) ((usec) * 1000)
#define MS_TO_US(msec) ((msec) * 1000)
#define IR_MAX_DURATION MS_TO_US(500)
#define IR_DEFAULT_TIMEOUT MS_TO_US(125)
void ir_raw_event_handle(struct rc_dev *dev);
int ir_raw_event_store(struct rc_dev *dev, struct ir_raw_event *ev);
int ir_raw_event_store_edge(struct rc_dev *dev, bool pulse);
int ir_raw_event_store_with_filter(struct rc_dev *dev,
struct ir_raw_event *ev);
int ir_raw_event_store_with_timeout(struct rc_dev *dev,
struct ir_raw_event *ev);
void ir_raw_event_set_idle(struct rc_dev *dev, bool idle);
int ir_raw_encode_scancode(enum rc_proto protocol, u32 scancode,
struct ir_raw_event *events, unsigned int max);
int ir_raw_encode_carrier(enum rc_proto protocol);
static inline void ir_raw_event_reset(struct rc_dev *dev)
{
ir_raw_event_store(dev, &((struct ir_raw_event) { .reset = true }));
dev->idle = true;
ir_raw_event_handle(dev);
}
/* extract mask bits out of data and pack them into the result */
static inline u32 ir_extract_bits(u32 data, u32 mask)
{
u32 vbit = 1, value = 0;
do {
if (mask & 1) {
if (data & 1)
value |= vbit;
vbit <<= 1;
}
data >>= 1;
} while (mask >>= 1);
return value;
}
/* Get NEC scancode and protocol type from address and command bytes */
static inline u32 ir_nec_bytes_to_scancode(u8 address, u8 not_address,
u8 command, u8 not_command,
enum rc_proto *protocol)
{
u32 scancode;
if ((command ^ not_command) != 0xff) {
/* NEC transport, but modified protocol, used by at
* least Apple and TiVo remotes
*/
scancode = not_address << 24 |
address << 16 |
not_command << 8 |
command;
*protocol = RC_PROTO_NEC32;
} else if ((address ^ not_address) != 0xff) {
/* Extended NEC */
scancode = address << 16 |
not_address << 8 |
command;
*protocol = RC_PROTO_NECX;
} else {
/* Normal NEC */
scancode = address << 8 | command;
*protocol = RC_PROTO_NEC;
}
return scancode;
}
#endif /* _RC_CORE */