xref: /linux/include/linux/kfifo.h (revision 266aa3b4812e97942a8ce5c7aafa7da059f7b5b8)
1 /* SPDX-License-Identifier: GPL-2.0-or-later */
2 /*
3  * A generic kernel FIFO implementation
4  *
5  * Copyright (C) 2013 Stefani Seibold <stefani@seibold.net>
6  */
7 
8 #ifndef _LINUX_KFIFO_H
9 #define _LINUX_KFIFO_H
10 
11 /*
12  * How to porting drivers to the new generic FIFO API:
13  *
14  * - Modify the declaration of the "struct kfifo *" object into a
15  *   in-place "struct kfifo" object
16  * - Init the in-place object with kfifo_alloc() or kfifo_init()
17  *   Note: The address of the in-place "struct kfifo" object must be
18  *   passed as the first argument to this functions
19  * - Replace the use of __kfifo_put into kfifo_in and __kfifo_get
20  *   into kfifo_out
21  * - Replace the use of kfifo_put into kfifo_in_spinlocked and kfifo_get
22  *   into kfifo_out_spinlocked
23  *   Note: the spinlock pointer formerly passed to kfifo_init/kfifo_alloc
24  *   must be passed now to the kfifo_in_spinlocked and kfifo_out_spinlocked
25  *   as the last parameter
26  * - The formerly __kfifo_* functions are renamed into kfifo_*
27  */
28 
29 /*
30  * Note about locking: There is no locking required until only one reader
31  * and one writer is using the fifo and no kfifo_reset() will be called.
32  * kfifo_reset_out() can be safely used, until it will be only called
33  * in the reader thread.
34  * For multiple writer and one reader there is only a need to lock the writer.
35  * And vice versa for only one writer and multiple reader there is only a need
36  * to lock the reader.
37  */
38 
39 #include <linux/array_size.h>
40 #include <linux/dma-mapping.h>
41 #include <linux/spinlock.h>
42 #include <linux/stddef.h>
43 #include <linux/types.h>
44 
45 #include <asm/barrier.h>
46 #include <asm/errno.h>
47 
48 struct scatterlist;
49 
50 struct __kfifo {
51 	unsigned int	in;
52 	unsigned int	out;
53 	unsigned int	mask;
54 	unsigned int	esize;
55 	void		*data;
56 };
57 
58 #define __STRUCT_KFIFO_COMMON(datatype, recsize, ptrtype) \
59 	union { \
60 		struct __kfifo	kfifo; \
61 		datatype	*type; \
62 		const datatype	*const_type; \
63 		char		(*rectype)[recsize]; \
64 		ptrtype		*ptr; \
65 		ptrtype const	*ptr_const; \
66 	}
67 
68 #define __STRUCT_KFIFO(type, size, recsize, ptrtype) \
69 { \
70 	__STRUCT_KFIFO_COMMON(type, recsize, ptrtype); \
71 	type		buf[((size < 2) || (size & (size - 1))) ? -1 : size]; \
72 }
73 
74 #define STRUCT_KFIFO(type, size) \
75 	struct __STRUCT_KFIFO(type, size, 0, type)
76 
77 #define __STRUCT_KFIFO_PTR(type, recsize, ptrtype) \
78 { \
79 	__STRUCT_KFIFO_COMMON(type, recsize, ptrtype); \
80 	type		buf[0]; \
81 }
82 
83 #define STRUCT_KFIFO_PTR(type) \
84 	struct __STRUCT_KFIFO_PTR(type, 0, type)
85 
86 /*
87  * define compatibility "struct kfifo" for dynamic allocated fifos
88  */
89 struct kfifo __STRUCT_KFIFO_PTR(unsigned char, 0, void);
90 
91 #define STRUCT_KFIFO_REC_1(size) \
92 	struct __STRUCT_KFIFO(unsigned char, size, 1, void)
93 
94 #define STRUCT_KFIFO_REC_2(size) \
95 	struct __STRUCT_KFIFO(unsigned char, size, 2, void)
96 
97 /*
98  * define kfifo_rec types
99  */
100 struct kfifo_rec_ptr_1 __STRUCT_KFIFO_PTR(unsigned char, 1, void);
101 struct kfifo_rec_ptr_2 __STRUCT_KFIFO_PTR(unsigned char, 2, void);
102 
103 /*
104  * helper macro to distinguish between real in place fifo where the fifo
105  * array is a part of the structure and the fifo type where the array is
106  * outside of the fifo structure.
107  */
108 #define	__is_kfifo_ptr(fifo) \
109 	(sizeof(*fifo) == sizeof(STRUCT_KFIFO_PTR(typeof(*(fifo)->type))))
110 
111 /**
112  * DECLARE_KFIFO_PTR - macro to declare a fifo pointer object
113  * @fifo: name of the declared fifo
114  * @type: type of the fifo elements
115  */
116 #define DECLARE_KFIFO_PTR(fifo, type)	STRUCT_KFIFO_PTR(type) fifo
117 
118 /**
119  * DECLARE_KFIFO - macro to declare a fifo object
120  * @fifo: name of the declared fifo
121  * @type: type of the fifo elements
122  * @size: the number of elements in the fifo, this must be a power of 2
123  */
124 #define DECLARE_KFIFO(fifo, type, size)	STRUCT_KFIFO(type, size) fifo
125 
126 /**
127  * INIT_KFIFO - Initialize a fifo declared by DECLARE_KFIFO
128  * @fifo: name of the declared fifo datatype
129  */
130 #define INIT_KFIFO(fifo) \
131 (void)({ \
132 	typeof(&(fifo)) __tmp = &(fifo); \
133 	struct __kfifo *__kfifo = &__tmp->kfifo; \
134 	__kfifo->in = 0; \
135 	__kfifo->out = 0; \
136 	__kfifo->mask = __is_kfifo_ptr(__tmp) ? 0 : ARRAY_SIZE(__tmp->buf) - 1;\
137 	__kfifo->esize = sizeof(*__tmp->buf); \
138 	__kfifo->data = __is_kfifo_ptr(__tmp) ?  NULL : __tmp->buf; \
139 })
140 
141 /**
142  * DEFINE_KFIFO - macro to define and initialize a fifo
143  * @fifo: name of the declared fifo datatype
144  * @type: type of the fifo elements
145  * @size: the number of elements in the fifo, this must be a power of 2
146  *
147  * Note: the macro can be used for global and local fifo data type variables.
148  */
149 #define DEFINE_KFIFO(fifo, type, size) \
150 	DECLARE_KFIFO(fifo, type, size) = \
151 	(typeof(fifo)) { \
152 		{ \
153 			{ \
154 			.in	= 0, \
155 			.out	= 0, \
156 			.mask	= __is_kfifo_ptr(&(fifo)) ? \
157 				  0 : \
158 				  ARRAY_SIZE((fifo).buf) - 1, \
159 			.esize	= sizeof(*(fifo).buf), \
160 			.data	= __is_kfifo_ptr(&(fifo)) ? \
161 				NULL : \
162 				(fifo).buf, \
163 			} \
164 		} \
165 	}
166 
167 
168 static inline unsigned int __must_check
169 __kfifo_uint_must_check_helper(unsigned int val)
170 {
171 	return val;
172 }
173 
174 static inline int __must_check
175 __kfifo_int_must_check_helper(int val)
176 {
177 	return val;
178 }
179 
180 /**
181  * kfifo_initialized - Check if the fifo is initialized
182  * @fifo: address of the fifo to check
183  *
184  * Return %true if fifo is initialized, otherwise %false.
185  * Assumes the fifo was 0 before.
186  */
187 #define kfifo_initialized(fifo) ((fifo)->kfifo.mask)
188 
189 /**
190  * kfifo_esize - returns the size of the element managed by the fifo
191  * @fifo: address of the fifo to be used
192  */
193 #define kfifo_esize(fifo)	((fifo)->kfifo.esize)
194 
195 /**
196  * kfifo_recsize - returns the size of the record length field
197  * @fifo: address of the fifo to be used
198  */
199 #define kfifo_recsize(fifo)	(sizeof(*(fifo)->rectype))
200 
201 /**
202  * kfifo_size - returns the size of the fifo in elements
203  * @fifo: address of the fifo to be used
204  */
205 #define kfifo_size(fifo)	((fifo)->kfifo.mask + 1)
206 
207 /**
208  * kfifo_reset - removes the entire fifo content
209  * @fifo: address of the fifo to be used
210  *
211  * Note: usage of kfifo_reset() is dangerous. It should be only called when the
212  * fifo is exclusived locked or when it is secured that no other thread is
213  * accessing the fifo.
214  */
215 #define kfifo_reset(fifo) \
216 (void)({ \
217 	typeof((fifo) + 1) __tmp = (fifo); \
218 	__tmp->kfifo.in = __tmp->kfifo.out = 0; \
219 })
220 
221 /**
222  * kfifo_reset_out - skip fifo content
223  * @fifo: address of the fifo to be used
224  *
225  * Note: The usage of kfifo_reset_out() is safe until it will be only called
226  * from the reader thread and there is only one concurrent reader. Otherwise
227  * it is dangerous and must be handled in the same way as kfifo_reset().
228  */
229 #define kfifo_reset_out(fifo)	\
230 (void)({ \
231 	typeof((fifo) + 1) __tmp = (fifo); \
232 	__tmp->kfifo.out = __tmp->kfifo.in; \
233 })
234 
235 /**
236  * kfifo_len - returns the number of used elements in the fifo
237  * @fifo: address of the fifo to be used
238  */
239 #define kfifo_len(fifo) \
240 ({ \
241 	typeof((fifo) + 1) __tmpl = (fifo); \
242 	__tmpl->kfifo.in - __tmpl->kfifo.out; \
243 })
244 
245 /**
246  * kfifo_is_empty - returns true if the fifo is empty
247  * @fifo: address of the fifo to be used
248  */
249 #define	kfifo_is_empty(fifo) \
250 ({ \
251 	typeof((fifo) + 1) __tmpq = (fifo); \
252 	__tmpq->kfifo.in == __tmpq->kfifo.out; \
253 })
254 
255 /**
256  * kfifo_is_empty_spinlocked - returns true if the fifo is empty using
257  * a spinlock for locking
258  * @fifo: address of the fifo to be used
259  * @lock: spinlock to be used for locking
260  */
261 #define kfifo_is_empty_spinlocked(fifo, lock) \
262 ({ \
263 	unsigned long __flags; \
264 	bool __ret; \
265 	spin_lock_irqsave(lock, __flags); \
266 	__ret = kfifo_is_empty(fifo); \
267 	spin_unlock_irqrestore(lock, __flags); \
268 	__ret; \
269 })
270 
271 /**
272  * kfifo_is_empty_spinlocked_noirqsave  - returns true if the fifo is empty
273  * using a spinlock for locking, doesn't disable interrupts
274  * @fifo: address of the fifo to be used
275  * @lock: spinlock to be used for locking
276  */
277 #define kfifo_is_empty_spinlocked_noirqsave(fifo, lock) \
278 ({ \
279 	bool __ret; \
280 	spin_lock(lock); \
281 	__ret = kfifo_is_empty(fifo); \
282 	spin_unlock(lock); \
283 	__ret; \
284 })
285 
286 /**
287  * kfifo_is_full - returns true if the fifo is full
288  * @fifo: address of the fifo to be used
289  */
290 #define	kfifo_is_full(fifo) \
291 ({ \
292 	typeof((fifo) + 1) __tmpq = (fifo); \
293 	kfifo_len(__tmpq) > __tmpq->kfifo.mask; \
294 })
295 
296 /**
297  * kfifo_avail - returns the number of unused elements in the fifo
298  * @fifo: address of the fifo to be used
299  */
300 #define	kfifo_avail(fifo) \
301 __kfifo_uint_must_check_helper( \
302 ({ \
303 	typeof((fifo) + 1) __tmpq = (fifo); \
304 	const size_t __recsize = sizeof(*__tmpq->rectype); \
305 	unsigned int __avail = kfifo_size(__tmpq) - kfifo_len(__tmpq); \
306 	(__recsize) ? ((__avail <= __recsize) ? 0 : \
307 	__kfifo_max_r(__avail - __recsize, __recsize)) : \
308 	__avail; \
309 }) \
310 )
311 
312 /**
313  * kfifo_skip_count - skip output data
314  * @fifo: address of the fifo to be used
315  * @count: count of data to skip
316  */
317 #define	kfifo_skip_count(fifo, count) do { \
318 	typeof((fifo) + 1) __tmp = (fifo); \
319 	const size_t __recsize = sizeof(*__tmp->rectype); \
320 	struct __kfifo *__kfifo = &__tmp->kfifo; \
321 	if (__recsize) \
322 		__kfifo_skip_r(__kfifo, __recsize); \
323 	else \
324 		__kfifo->out += (count); \
325 } while(0)
326 
327 /**
328  * kfifo_skip - skip output data
329  * @fifo: address of the fifo to be used
330  */
331 #define	kfifo_skip(fifo)	kfifo_skip_count(fifo, 1)
332 
333 /**
334  * kfifo_peek_len - gets the size of the next fifo record
335  * @fifo: address of the fifo to be used
336  *
337  * This function returns the size of the next fifo record in number of bytes.
338  */
339 #define kfifo_peek_len(fifo) \
340 __kfifo_uint_must_check_helper( \
341 ({ \
342 	typeof((fifo) + 1) __tmp = (fifo); \
343 	const size_t __recsize = sizeof(*__tmp->rectype); \
344 	struct __kfifo *__kfifo = &__tmp->kfifo; \
345 	(!__recsize) ? kfifo_len(__tmp) * sizeof(*__tmp->type) : \
346 	__kfifo_len_r(__kfifo, __recsize); \
347 }) \
348 )
349 
350 /**
351  * kfifo_alloc - dynamically allocates a new fifo buffer
352  * @fifo: pointer to the fifo
353  * @size: the number of elements in the fifo, this must be a power of 2
354  * @gfp_mask: get_free_pages mask, passed to kmalloc()
355  *
356  * This macro dynamically allocates a new fifo buffer.
357  *
358  * The number of elements will be rounded-up to a power of 2.
359  * The fifo will be release with kfifo_free().
360  * Return 0 if no error, otherwise an error code.
361  */
362 #define kfifo_alloc(fifo, size, gfp_mask) \
363 __kfifo_int_must_check_helper( \
364 ({ \
365 	typeof((fifo) + 1) __tmp = (fifo); \
366 	struct __kfifo *__kfifo = &__tmp->kfifo; \
367 	__is_kfifo_ptr(__tmp) ? \
368 	__kfifo_alloc(__kfifo, size, sizeof(*__tmp->type), gfp_mask) : \
369 	-EINVAL; \
370 }) \
371 )
372 
373 /**
374  * kfifo_free - frees the fifo
375  * @fifo: the fifo to be freed
376  */
377 #define kfifo_free(fifo) \
378 ({ \
379 	typeof((fifo) + 1) __tmp = (fifo); \
380 	struct __kfifo *__kfifo = &__tmp->kfifo; \
381 	if (__is_kfifo_ptr(__tmp)) \
382 		__kfifo_free(__kfifo); \
383 })
384 
385 /**
386  * kfifo_init - initialize a fifo using a preallocated buffer
387  * @fifo: the fifo to assign the buffer
388  * @buffer: the preallocated buffer to be used
389  * @size: the size of the internal buffer, this have to be a power of 2
390  *
391  * This macro initializes a fifo using a preallocated buffer.
392  *
393  * The number of elements will be rounded-up to a power of 2.
394  * Return 0 if no error, otherwise an error code.
395  */
396 #define kfifo_init(fifo, buffer, size) \
397 ({ \
398 	typeof((fifo) + 1) __tmp = (fifo); \
399 	struct __kfifo *__kfifo = &__tmp->kfifo; \
400 	__is_kfifo_ptr(__tmp) ? \
401 	__kfifo_init(__kfifo, buffer, size, sizeof(*__tmp->type)) : \
402 	-EINVAL; \
403 })
404 
405 /**
406  * kfifo_put - put data into the fifo
407  * @fifo: address of the fifo to be used
408  * @val: the data to be added
409  *
410  * This macro copies the given value into the fifo.
411  * It returns 0 if the fifo was full. Otherwise it returns the number
412  * processed elements.
413  *
414  * Note that with only one concurrent reader and one concurrent
415  * writer, you don't need extra locking to use these macro.
416  */
417 #define	kfifo_put(fifo, val) \
418 ({ \
419 	typeof((fifo) + 1) __tmp = (fifo); \
420 	typeof(*__tmp->const_type) __val = (val); \
421 	unsigned int __ret; \
422 	size_t __recsize = sizeof(*__tmp->rectype); \
423 	struct __kfifo *__kfifo = &__tmp->kfifo; \
424 	if (__recsize) \
425 		__ret = __kfifo_in_r(__kfifo, &__val, sizeof(__val), \
426 			__recsize); \
427 	else { \
428 		__ret = !kfifo_is_full(__tmp); \
429 		if (__ret) { \
430 			(__is_kfifo_ptr(__tmp) ? \
431 			((typeof(__tmp->type))__kfifo->data) : \
432 			(__tmp->buf) \
433 			)[__kfifo->in & __tmp->kfifo.mask] = \
434 				*(typeof(__tmp->type))&__val; \
435 			smp_wmb(); \
436 			__kfifo->in++; \
437 		} \
438 	} \
439 	__ret; \
440 })
441 
442 /**
443  * kfifo_get - get data from the fifo
444  * @fifo: address of the fifo to be used
445  * @val: address where to store the data
446  *
447  * This macro reads the data from the fifo.
448  * It returns 0 if the fifo was empty. Otherwise it returns the number
449  * processed elements.
450  *
451  * Note that with only one concurrent reader and one concurrent
452  * writer, you don't need extra locking to use these macro.
453  */
454 #define	kfifo_get(fifo, val) \
455 __kfifo_uint_must_check_helper( \
456 ({ \
457 	typeof((fifo) + 1) __tmp = (fifo); \
458 	typeof(__tmp->ptr) __val = (val); \
459 	unsigned int __ret; \
460 	const size_t __recsize = sizeof(*__tmp->rectype); \
461 	struct __kfifo *__kfifo = &__tmp->kfifo; \
462 	if (__recsize) \
463 		__ret = __kfifo_out_r(__kfifo, __val, sizeof(*__val), \
464 			__recsize); \
465 	else { \
466 		__ret = !kfifo_is_empty(__tmp); \
467 		if (__ret) { \
468 			*(typeof(__tmp->type))__val = \
469 				(__is_kfifo_ptr(__tmp) ? \
470 				((typeof(__tmp->type))__kfifo->data) : \
471 				(__tmp->buf) \
472 				)[__kfifo->out & __tmp->kfifo.mask]; \
473 			smp_wmb(); \
474 			__kfifo->out++; \
475 		} \
476 	} \
477 	__ret; \
478 }) \
479 )
480 
481 /**
482  * kfifo_peek - get data from the fifo without removing
483  * @fifo: address of the fifo to be used
484  * @val: address where to store the data
485  *
486  * This reads the data from the fifo without removing it from the fifo.
487  * It returns 0 if the fifo was empty. Otherwise it returns the number
488  * processed elements.
489  *
490  * Note that with only one concurrent reader and one concurrent
491  * writer, you don't need extra locking to use these macro.
492  */
493 #define	kfifo_peek(fifo, val) \
494 __kfifo_uint_must_check_helper( \
495 ({ \
496 	typeof((fifo) + 1) __tmp = (fifo); \
497 	typeof(__tmp->ptr) __val = (val); \
498 	unsigned int __ret; \
499 	const size_t __recsize = sizeof(*__tmp->rectype); \
500 	struct __kfifo *__kfifo = &__tmp->kfifo; \
501 	if (__recsize) \
502 		__ret = __kfifo_out_peek_r(__kfifo, __val, sizeof(*__val), \
503 			__recsize); \
504 	else { \
505 		__ret = !kfifo_is_empty(__tmp); \
506 		if (__ret) { \
507 			*(typeof(__tmp->type))__val = \
508 				(__is_kfifo_ptr(__tmp) ? \
509 				((typeof(__tmp->type))__kfifo->data) : \
510 				(__tmp->buf) \
511 				)[__kfifo->out & __tmp->kfifo.mask]; \
512 			smp_wmb(); \
513 		} \
514 	} \
515 	__ret; \
516 }) \
517 )
518 
519 /**
520  * kfifo_in - put data into the fifo
521  * @fifo: address of the fifo to be used
522  * @buf: the data to be added
523  * @n: number of elements to be added
524  *
525  * This macro copies the given buffer into the fifo and returns the
526  * number of copied elements.
527  *
528  * Note that with only one concurrent reader and one concurrent
529  * writer, you don't need extra locking to use these macro.
530  */
531 #define	kfifo_in(fifo, buf, n) \
532 ({ \
533 	typeof((fifo) + 1) __tmp = (fifo); \
534 	typeof(__tmp->ptr_const) __buf = (buf); \
535 	unsigned long __n = (n); \
536 	const size_t __recsize = sizeof(*__tmp->rectype); \
537 	struct __kfifo *__kfifo = &__tmp->kfifo; \
538 	(__recsize) ?\
539 	__kfifo_in_r(__kfifo, __buf, __n, __recsize) : \
540 	__kfifo_in(__kfifo, __buf, __n); \
541 })
542 
543 /**
544  * kfifo_in_spinlocked - put data into the fifo using a spinlock for locking
545  * @fifo: address of the fifo to be used
546  * @buf: the data to be added
547  * @n: number of elements to be added
548  * @lock: pointer to the spinlock to use for locking
549  *
550  * This macro copies the given values buffer into the fifo and returns the
551  * number of copied elements.
552  */
553 #define	kfifo_in_spinlocked(fifo, buf, n, lock) \
554 ({ \
555 	unsigned long __flags; \
556 	unsigned int __ret; \
557 	spin_lock_irqsave(lock, __flags); \
558 	__ret = kfifo_in(fifo, buf, n); \
559 	spin_unlock_irqrestore(lock, __flags); \
560 	__ret; \
561 })
562 
563 /**
564  * kfifo_in_spinlocked_noirqsave - put data into fifo using a spinlock for
565  * locking, don't disable interrupts
566  * @fifo: address of the fifo to be used
567  * @buf: the data to be added
568  * @n: number of elements to be added
569  * @lock: pointer to the spinlock to use for locking
570  *
571  * This is a variant of kfifo_in_spinlocked() but uses spin_lock/unlock()
572  * for locking and doesn't disable interrupts.
573  */
574 #define kfifo_in_spinlocked_noirqsave(fifo, buf, n, lock) \
575 ({ \
576 	unsigned int __ret; \
577 	spin_lock(lock); \
578 	__ret = kfifo_in(fifo, buf, n); \
579 	spin_unlock(lock); \
580 	__ret; \
581 })
582 
583 /* alias for kfifo_in_spinlocked, will be removed in a future release */
584 #define kfifo_in_locked(fifo, buf, n, lock) \
585 		kfifo_in_spinlocked(fifo, buf, n, lock)
586 
587 /**
588  * kfifo_out - get data from the fifo
589  * @fifo: address of the fifo to be used
590  * @buf: pointer to the storage buffer
591  * @n: max. number of elements to get
592  *
593  * This macro gets some data from the fifo and returns the numbers of elements
594  * copied.
595  *
596  * Note that with only one concurrent reader and one concurrent
597  * writer, you don't need extra locking to use these macro.
598  */
599 #define	kfifo_out(fifo, buf, n) \
600 __kfifo_uint_must_check_helper( \
601 ({ \
602 	typeof((fifo) + 1) __tmp = (fifo); \
603 	typeof(__tmp->ptr) __buf = (buf); \
604 	unsigned long __n = (n); \
605 	const size_t __recsize = sizeof(*__tmp->rectype); \
606 	struct __kfifo *__kfifo = &__tmp->kfifo; \
607 	(__recsize) ?\
608 	__kfifo_out_r(__kfifo, __buf, __n, __recsize) : \
609 	__kfifo_out(__kfifo, __buf, __n); \
610 }) \
611 )
612 
613 /**
614  * kfifo_out_spinlocked - get data from the fifo using a spinlock for locking
615  * @fifo: address of the fifo to be used
616  * @buf: pointer to the storage buffer
617  * @n: max. number of elements to get
618  * @lock: pointer to the spinlock to use for locking
619  *
620  * This macro gets the data from the fifo and returns the numbers of elements
621  * copied.
622  */
623 #define	kfifo_out_spinlocked(fifo, buf, n, lock) \
624 __kfifo_uint_must_check_helper( \
625 ({ \
626 	unsigned long __flags; \
627 	unsigned int __ret; \
628 	spin_lock_irqsave(lock, __flags); \
629 	__ret = kfifo_out(fifo, buf, n); \
630 	spin_unlock_irqrestore(lock, __flags); \
631 	__ret; \
632 }) \
633 )
634 
635 /**
636  * kfifo_out_spinlocked_noirqsave - get data from the fifo using a spinlock
637  * for locking, don't disable interrupts
638  * @fifo: address of the fifo to be used
639  * @buf: pointer to the storage buffer
640  * @n: max. number of elements to get
641  * @lock: pointer to the spinlock to use for locking
642  *
643  * This is a variant of kfifo_out_spinlocked() which uses spin_lock/unlock()
644  * for locking and doesn't disable interrupts.
645  */
646 #define kfifo_out_spinlocked_noirqsave(fifo, buf, n, lock) \
647 __kfifo_uint_must_check_helper( \
648 ({ \
649 	unsigned int __ret; \
650 	spin_lock(lock); \
651 	__ret = kfifo_out(fifo, buf, n); \
652 	spin_unlock(lock); \
653 	__ret; \
654 }) \
655 )
656 
657 /* alias for kfifo_out_spinlocked, will be removed in a future release */
658 #define kfifo_out_locked(fifo, buf, n, lock) \
659 		kfifo_out_spinlocked(fifo, buf, n, lock)
660 
661 /**
662  * kfifo_from_user - puts some data from user space into the fifo
663  * @fifo: address of the fifo to be used
664  * @from: pointer to the data to be added
665  * @len: the length of the data to be added
666  * @copied: pointer to output variable to store the number of copied bytes
667  *
668  * This macro copies at most @len bytes from the @from into the
669  * fifo, depending of the available space and returns -EFAULT/0.
670  *
671  * Note that with only one concurrent reader and one concurrent
672  * writer, you don't need extra locking to use these macro.
673  */
674 #define	kfifo_from_user(fifo, from, len, copied) \
675 __kfifo_uint_must_check_helper( \
676 ({ \
677 	typeof((fifo) + 1) __tmp = (fifo); \
678 	const void __user *__from = (from); \
679 	unsigned int __len = (len); \
680 	unsigned int *__copied = (copied); \
681 	const size_t __recsize = sizeof(*__tmp->rectype); \
682 	struct __kfifo *__kfifo = &__tmp->kfifo; \
683 	(__recsize) ? \
684 	__kfifo_from_user_r(__kfifo, __from, __len,  __copied, __recsize) : \
685 	__kfifo_from_user(__kfifo, __from, __len, __copied); \
686 }) \
687 )
688 
689 /**
690  * kfifo_to_user - copies data from the fifo into user space
691  * @fifo: address of the fifo to be used
692  * @to: where the data must be copied
693  * @len: the size of the destination buffer
694  * @copied: pointer to output variable to store the number of copied bytes
695  *
696  * This macro copies at most @len bytes from the fifo into the
697  * @to buffer and returns -EFAULT/0.
698  *
699  * Note that with only one concurrent reader and one concurrent
700  * writer, you don't need extra locking to use these macro.
701  */
702 #define	kfifo_to_user(fifo, to, len, copied) \
703 __kfifo_int_must_check_helper( \
704 ({ \
705 	typeof((fifo) + 1) __tmp = (fifo); \
706 	void __user *__to = (to); \
707 	unsigned int __len = (len); \
708 	unsigned int *__copied = (copied); \
709 	const size_t __recsize = sizeof(*__tmp->rectype); \
710 	struct __kfifo *__kfifo = &__tmp->kfifo; \
711 	(__recsize) ? \
712 	__kfifo_to_user_r(__kfifo, __to, __len, __copied, __recsize) : \
713 	__kfifo_to_user(__kfifo, __to, __len, __copied); \
714 }) \
715 )
716 
717 /**
718  * kfifo_dma_in_prepare_mapped - setup a scatterlist for DMA input
719  * @fifo: address of the fifo to be used
720  * @sgl: pointer to the scatterlist array
721  * @nents: number of entries in the scatterlist array
722  * @len: number of elements to transfer
723  * @dma: mapped dma address to fill into @sgl
724  *
725  * This macro fills a scatterlist for DMA input.
726  * It returns the number entries in the scatterlist array.
727  *
728  * Note that with only one concurrent reader and one concurrent
729  * writer, you don't need extra locking to use these macros.
730  */
731 #define	kfifo_dma_in_prepare_mapped(fifo, sgl, nents, len, dma) \
732 ({ \
733 	typeof((fifo) + 1) __tmp = (fifo); \
734 	struct scatterlist *__sgl = (sgl); \
735 	int __nents = (nents); \
736 	unsigned int __len = (len); \
737 	const size_t __recsize = sizeof(*__tmp->rectype); \
738 	struct __kfifo *__kfifo = &__tmp->kfifo; \
739 	(__recsize) ? \
740 	__kfifo_dma_in_prepare_r(__kfifo, __sgl, __nents, __len, __recsize, \
741 				 dma) : \
742 	__kfifo_dma_in_prepare(__kfifo, __sgl, __nents, __len, dma); \
743 })
744 
745 #define kfifo_dma_in_prepare(fifo, sgl, nents, len) \
746 	kfifo_dma_in_prepare_mapped(fifo, sgl, nents, len, DMA_MAPPING_ERROR)
747 
748 /**
749  * kfifo_dma_in_finish - finish a DMA IN operation
750  * @fifo: address of the fifo to be used
751  * @len: number of bytes to received
752  *
753  * This macro finishes a DMA IN operation. The in counter will be updated by
754  * the len parameter. No error checking will be done.
755  *
756  * Note that with only one concurrent reader and one concurrent
757  * writer, you don't need extra locking to use these macros.
758  */
759 #define kfifo_dma_in_finish(fifo, len) \
760 (void)({ \
761 	typeof((fifo) + 1) __tmp = (fifo); \
762 	unsigned int __len = (len); \
763 	const size_t __recsize = sizeof(*__tmp->rectype); \
764 	struct __kfifo *__kfifo = &__tmp->kfifo; \
765 	if (__recsize) \
766 		__kfifo_dma_in_finish_r(__kfifo, __len, __recsize); \
767 	else \
768 		__kfifo->in += __len / sizeof(*__tmp->type); \
769 })
770 
771 /**
772  * kfifo_dma_out_prepare_mapped - setup a scatterlist for DMA output
773  * @fifo: address of the fifo to be used
774  * @sgl: pointer to the scatterlist array
775  * @nents: number of entries in the scatterlist array
776  * @len: number of elements to transfer
777  * @dma: mapped dma address to fill into @sgl
778  *
779  * This macro fills a scatterlist for DMA output which at most @len bytes
780  * to transfer.
781  * It returns the number entries in the scatterlist array.
782  * A zero means there is no space available and the scatterlist is not filled.
783  *
784  * Note that with only one concurrent reader and one concurrent
785  * writer, you don't need extra locking to use these macros.
786  */
787 #define	kfifo_dma_out_prepare_mapped(fifo, sgl, nents, len, dma) \
788 ({ \
789 	typeof((fifo) + 1) __tmp = (fifo);  \
790 	struct scatterlist *__sgl = (sgl); \
791 	int __nents = (nents); \
792 	unsigned int __len = (len); \
793 	const size_t __recsize = sizeof(*__tmp->rectype); \
794 	struct __kfifo *__kfifo = &__tmp->kfifo; \
795 	(__recsize) ? \
796 	__kfifo_dma_out_prepare_r(__kfifo, __sgl, __nents, __len, __recsize, \
797 				  dma) : \
798 	__kfifo_dma_out_prepare(__kfifo, __sgl, __nents, __len, dma); \
799 })
800 
801 #define	kfifo_dma_out_prepare(fifo, sgl, nents, len) \
802 	kfifo_dma_out_prepare_mapped(fifo, sgl, nents, len, DMA_MAPPING_ERROR)
803 
804 /**
805  * kfifo_dma_out_finish - finish a DMA OUT operation
806  * @fifo: address of the fifo to be used
807  * @len: number of bytes transferred
808  *
809  * This macro finishes a DMA OUT operation. The out counter will be updated by
810  * the len parameter. No error checking will be done.
811  *
812  * Note that with only one concurrent reader and one concurrent
813  * writer, you don't need extra locking to use these macros.
814  */
815 #define kfifo_dma_out_finish(fifo, len) do { \
816 	typeof((fifo) + 1) ___tmp = (fifo); \
817 	kfifo_skip_count(___tmp, (len) / sizeof(*___tmp->type)); \
818 } while (0)
819 
820 /**
821  * kfifo_out_peek - gets some data from the fifo
822  * @fifo: address of the fifo to be used
823  * @buf: pointer to the storage buffer
824  * @n: max. number of elements to get
825  *
826  * This macro gets the data from the fifo and returns the numbers of elements
827  * copied. The data is not removed from the fifo.
828  *
829  * Note that with only one concurrent reader and one concurrent
830  * writer, you don't need extra locking to use these macro.
831  */
832 #define	kfifo_out_peek(fifo, buf, n) \
833 __kfifo_uint_must_check_helper( \
834 ({ \
835 	typeof((fifo) + 1) __tmp = (fifo); \
836 	typeof(__tmp->ptr) __buf = (buf); \
837 	unsigned long __n = (n); \
838 	const size_t __recsize = sizeof(*__tmp->rectype); \
839 	struct __kfifo *__kfifo = &__tmp->kfifo; \
840 	(__recsize) ? \
841 	__kfifo_out_peek_r(__kfifo, __buf, __n, __recsize) : \
842 	__kfifo_out_peek(__kfifo, __buf, __n); \
843 }) \
844 )
845 
846 /**
847  * kfifo_out_linear - gets a tail of/offset to available data
848  * @fifo: address of the fifo to be used
849  * @tail: pointer to an unsigned int to store the value of tail
850  * @n: max. number of elements to point at
851  *
852  * This macro obtains the offset (tail) to the available data in the fifo
853  * buffer and returns the
854  * numbers of elements available. It returns the available count till the end
855  * of data or till the end of the buffer. So that it can be used for linear
856  * data processing (like memcpy() of (@fifo->data + @tail) with count
857  * returned).
858  *
859  * Note that with only one concurrent reader and one concurrent
860  * writer, you don't need extra locking to use these macro.
861  */
862 #define kfifo_out_linear(fifo, tail, n) \
863 __kfifo_uint_must_check_helper( \
864 ({ \
865 	typeof((fifo) + 1) __tmp = (fifo); \
866 	unsigned int *__tail = (tail); \
867 	unsigned long __n = (n); \
868 	const size_t __recsize = sizeof(*__tmp->rectype); \
869 	struct __kfifo *__kfifo = &__tmp->kfifo; \
870 	(__recsize) ? \
871 	__kfifo_out_linear_r(__kfifo, __tail, __n, __recsize) : \
872 	__kfifo_out_linear(__kfifo, __tail, __n); \
873 }) \
874 )
875 
876 /**
877  * kfifo_out_linear_ptr - gets a pointer to the available data
878  * @fifo: address of the fifo to be used
879  * @ptr: pointer to data to store the pointer to tail
880  * @n: max. number of elements to point at
881  *
882  * Similarly to kfifo_out_linear(), this macro obtains the pointer to the
883  * available data in the fifo buffer and returns the numbers of elements
884  * available. It returns the available count till the end of available data or
885  * till the end of the buffer. So that it can be used for linear data
886  * processing (like memcpy() of @ptr with count returned).
887  *
888  * Note that with only one concurrent reader and one concurrent
889  * writer, you don't need extra locking to use these macro.
890  */
891 #define kfifo_out_linear_ptr(fifo, ptr, n) \
892 __kfifo_uint_must_check_helper( \
893 ({ \
894 	typeof((fifo) + 1) ___tmp = (fifo); \
895 	unsigned int ___tail; \
896 	unsigned int ___n = kfifo_out_linear(___tmp, &___tail, (n)); \
897 	*(ptr) = ___tmp->kfifo.data + ___tail * kfifo_esize(___tmp); \
898 	___n; \
899 }) \
900 )
901 
902 
903 extern int __kfifo_alloc(struct __kfifo *fifo, unsigned int size,
904 	size_t esize, gfp_t gfp_mask);
905 
906 extern void __kfifo_free(struct __kfifo *fifo);
907 
908 extern int __kfifo_init(struct __kfifo *fifo, void *buffer,
909 	unsigned int size, size_t esize);
910 
911 extern unsigned int __kfifo_in(struct __kfifo *fifo,
912 	const void *buf, unsigned int len);
913 
914 extern unsigned int __kfifo_out(struct __kfifo *fifo,
915 	void *buf, unsigned int len);
916 
917 extern int __kfifo_from_user(struct __kfifo *fifo,
918 	const void __user *from, unsigned long len, unsigned int *copied);
919 
920 extern int __kfifo_to_user(struct __kfifo *fifo,
921 	void __user *to, unsigned long len, unsigned int *copied);
922 
923 extern unsigned int __kfifo_dma_in_prepare(struct __kfifo *fifo,
924 	struct scatterlist *sgl, int nents, unsigned int len, dma_addr_t dma);
925 
926 extern unsigned int __kfifo_dma_out_prepare(struct __kfifo *fifo,
927 	struct scatterlist *sgl, int nents, unsigned int len, dma_addr_t dma);
928 
929 extern unsigned int __kfifo_out_peek(struct __kfifo *fifo,
930 	void *buf, unsigned int len);
931 
932 extern unsigned int __kfifo_out_linear(struct __kfifo *fifo,
933 	unsigned int *tail, unsigned int n);
934 
935 extern unsigned int __kfifo_in_r(struct __kfifo *fifo,
936 	const void *buf, unsigned int len, size_t recsize);
937 
938 extern unsigned int __kfifo_out_r(struct __kfifo *fifo,
939 	void *buf, unsigned int len, size_t recsize);
940 
941 extern int __kfifo_from_user_r(struct __kfifo *fifo,
942 	const void __user *from, unsigned long len, unsigned int *copied,
943 	size_t recsize);
944 
945 extern int __kfifo_to_user_r(struct __kfifo *fifo, void __user *to,
946 	unsigned long len, unsigned int *copied, size_t recsize);
947 
948 extern unsigned int __kfifo_dma_in_prepare_r(struct __kfifo *fifo,
949 	struct scatterlist *sgl, int nents, unsigned int len, size_t recsize,
950 	dma_addr_t dma);
951 
952 extern void __kfifo_dma_in_finish_r(struct __kfifo *fifo,
953 	unsigned int len, size_t recsize);
954 
955 extern unsigned int __kfifo_dma_out_prepare_r(struct __kfifo *fifo,
956 	struct scatterlist *sgl, int nents, unsigned int len, size_t recsize,
957 	dma_addr_t dma);
958 
959 extern unsigned int __kfifo_len_r(struct __kfifo *fifo, size_t recsize);
960 
961 extern void __kfifo_skip_r(struct __kfifo *fifo, size_t recsize);
962 
963 extern unsigned int __kfifo_out_peek_r(struct __kfifo *fifo,
964 	void *buf, unsigned int len, size_t recsize);
965 
966 extern unsigned int __kfifo_out_linear_r(struct __kfifo *fifo,
967 	unsigned int *tail, unsigned int n, size_t recsize);
968 
969 extern unsigned int __kfifo_max_r(unsigned int len, size_t recsize);
970 
971 #endif
972