GIF89a;
Direktori : /usr/src/kernels/3.10.0-1160.83.1.el7.centos.plus.x86_64/include/media/ |
Current File : //usr/src/kernels/3.10.0-1160.83.1.el7.centos.plus.x86_64/include/media/lirc_dev.h |
/* * LIRC base driver * * by Artur Lipowski <alipowski@interia.pl> * This code is licensed under GNU GPL * */ #ifndef _LINUX_LIRC_DEV_H #define _LINUX_LIRC_DEV_H #define MAX_IRCTL_DEVICES 8 #define BUFLEN 16 #define mod(n, div) ((n) % (div)) #include <linux/slab.h> #include <linux/fs.h> #include <linux/ioctl.h> #include <linux/poll.h> #include <linux/kfifo.h> #include <media/lirc.h> struct lirc_buffer { wait_queue_head_t wait_poll; spinlock_t fifo_lock; unsigned int chunk_size; unsigned int size; /* in chunks */ /* Using chunks instead of bytes pretends to simplify boundary checking * And should allow for some performance fine tunning later */ struct kfifo fifo; u8 fifo_initialized; }; static inline void lirc_buffer_clear(struct lirc_buffer *buf) { unsigned long flags; if (buf->fifo_initialized) { spin_lock_irqsave(&buf->fifo_lock, flags); kfifo_reset(&buf->fifo); spin_unlock_irqrestore(&buf->fifo_lock, flags); } else WARN(1, "calling %s on an uninitialized lirc_buffer\n", __func__); } static inline int lirc_buffer_init(struct lirc_buffer *buf, unsigned int chunk_size, unsigned int size) { int ret; init_waitqueue_head(&buf->wait_poll); spin_lock_init(&buf->fifo_lock); buf->chunk_size = chunk_size; buf->size = size; ret = kfifo_alloc(&buf->fifo, size * chunk_size, GFP_KERNEL); if (ret == 0) buf->fifo_initialized = 1; return ret; } static inline void lirc_buffer_free(struct lirc_buffer *buf) { if (buf->fifo_initialized) { kfifo_free(&buf->fifo); buf->fifo_initialized = 0; } else WARN(1, "calling %s on an uninitialized lirc_buffer\n", __func__); } static inline int lirc_buffer_len(struct lirc_buffer *buf) { int len; unsigned long flags; spin_lock_irqsave(&buf->fifo_lock, flags); len = kfifo_len(&buf->fifo); spin_unlock_irqrestore(&buf->fifo_lock, flags); return len; } static inline int lirc_buffer_full(struct lirc_buffer *buf) { return lirc_buffer_len(buf) == buf->size * buf->chunk_size; } static inline int lirc_buffer_empty(struct lirc_buffer *buf) { return !lirc_buffer_len(buf); } static inline int lirc_buffer_available(struct lirc_buffer *buf) { return buf->size - (lirc_buffer_len(buf) / buf->chunk_size); } static inline unsigned int lirc_buffer_read(struct lirc_buffer *buf, unsigned char *dest) { unsigned int ret = 0; if (lirc_buffer_len(buf) >= buf->chunk_size) ret = kfifo_out_locked(&buf->fifo, dest, buf->chunk_size, &buf->fifo_lock); return ret; } static inline unsigned int lirc_buffer_write(struct lirc_buffer *buf, unsigned char *orig) { unsigned int ret; ret = kfifo_in_locked(&buf->fifo, orig, buf->chunk_size, &buf->fifo_lock); return ret; } struct lirc_driver { char name[40]; int minor; __u32 code_length; unsigned int buffer_size; /* in chunks holding one code each */ int sample_rate; __u32 features; unsigned int chunk_size; void *data; int min_timeout; int max_timeout; int (*add_to_buf) (void *data, struct lirc_buffer *buf); struct lirc_buffer *rbuf; int (*set_use_inc) (void *data); void (*set_use_dec) (void *data); const struct file_operations *fops; struct device *dev; struct module *owner; }; /* name: * this string will be used for logs * * minor: * indicates minor device (/dev/lirc) number for registered driver * if caller fills it with negative value, then the first free minor * number will be used (if available) * * code_length: * length of the remote control key code expressed in bits * * sample_rate: * * data: * it may point to any driver data and this pointer will be passed to * all callback functions * * add_to_buf: * add_to_buf will be called after specified period of the time or * triggered by the external event, this behavior depends on value of * the sample_rate this function will be called in user context. This * routine should return 0 if data was added to the buffer and * -ENODATA if none was available. This should add some number of bits * evenly divisible by code_length to the buffer * * rbuf: * if not NULL, it will be used as a read buffer, you will have to * write to the buffer by other means, like irq's (see also * lirc_serial.c). * * set_use_inc: * set_use_inc will be called after device is opened * * set_use_dec: * set_use_dec will be called after device is closed * * fops: * file_operations for drivers which don't fit the current driver model. * * Some ioctl's can be directly handled by lirc_dev if the driver's * ioctl function is NULL or if it returns -ENOIOCTLCMD (see also * lirc_serial.c). * * owner: * the module owning this struct * */ /* following functions can be called ONLY from user context * * returns negative value on error or minor number * of the registered device if success * contents of the structure pointed by p is copied */ extern int lirc_register_driver(struct lirc_driver *d); /* returns negative value on error or 0 if success */ extern int lirc_unregister_driver(int minor); /* Returns the private data stored in the lirc_driver * associated with the given device file pointer. */ void *lirc_get_pdata(struct file *file); /* default file operations * used by drivers if they override only some operations */ int lirc_dev_fop_open(struct inode *inode, struct file *file); int lirc_dev_fop_close(struct inode *inode, struct file *file); unsigned int lirc_dev_fop_poll(struct file *file, poll_table *wait); long lirc_dev_fop_ioctl(struct file *file, unsigned int cmd, unsigned long arg); ssize_t lirc_dev_fop_read(struct file *file, char __user *buffer, size_t length, loff_t *ppos); ssize_t lirc_dev_fop_write(struct file *file, const char __user *buffer, size_t length, loff_t *ppos); #endif