tjh.dev / kernel
Linux kernel mirror (for testing) git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git
kernel os linux
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kernel / include / linux / kfifo.h
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1/* 2 * A generic kernel FIFO implementation 3 * 4 * Copyright (C) 2009/2010 Stefani Seibold <stefani@seibold.net> 5 * 6 * This program is free software; you can redistribute it and/or modify 7 * it under the terms of the GNU General Public License as published by 8 * the Free Software Foundation; either version 2 of the License, or 9 * (at your option) any later version. 10 * 11 * This program is distributed in the hope that it will be useful, 12 * but WITHOUT ANY WARRANTY; without even the implied warranty of 13 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 14 * GNU General Public License for more details. 15 * 16 * You should have received a copy of the GNU General Public License 17 * along with this program; if not, write to the Free Software 18 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. 19 * 20 */ 21 22#ifndef _LINUX_KFIFO_H 23#define _LINUX_KFIFO_H 24 25/* 26 * How to porting drivers to the new generic FIFO API: 27 * 28 * - Modify the declaration of the "struct kfifo *" object into a 29 * in-place "struct kfifo" object 30 * - Init the in-place object with kfifo_alloc() or kfifo_init() 31 * Note: The address of the in-place "struct kfifo" object must be 32 * passed as the first argument to this functions 33 * - Replace the use of __kfifo_put into kfifo_in and __kfifo_get 34 * into kfifo_out 35 * - Replace the use of kfifo_put into kfifo_in_spinlocked and kfifo_get 36 * into kfifo_out_spinlocked 37 * Note: the spinlock pointer formerly passed to kfifo_init/kfifo_alloc 38 * must be passed now to the kfifo_in_spinlocked and kfifo_out_spinlocked 39 * as the last parameter 40 * - The formerly __kfifo_* functions are renamed into kfifo_* 41 */ 42 43/* 44 * Note about locking : There is no locking required until only * one reader 45 * and one writer is using the fifo and no kfifo_reset() will be * called 46 * kfifo_reset_out() can be safely used, until it will be only called 47 * in the reader thread. 48 * For multiple writer and one reader there is only a need to lock the writer. 49 * And vice versa for only one writer and multiple reader there is only a need 50 * to lock the reader. 51 */ 52 53#include <linux/kernel.h> 54#include <linux/spinlock.h> 55#include <linux/stddef.h> 56#include <linux/scatterlist.h> 57 58struct __kfifo { 59 unsigned int in; 60 unsigned int out; 61 unsigned int mask; 62 unsigned int esize; 63 void *data; 64}; 65 66#define __STRUCT_KFIFO_COMMON(datatype, recsize, ptrtype) \ 67 union { \ 68 struct __kfifo kfifo; \ 69 datatype *type; \ 70 char (*rectype)[recsize]; \ 71 ptrtype *ptr; \ 72 const ptrtype *ptr_const; \ 73 } 74 75#define __STRUCT_KFIFO(type, size, recsize, ptrtype) \ 76{ \ 77 __STRUCT_KFIFO_COMMON(type, recsize, ptrtype); \ 78 type buf[((size < 2) || (size & (size - 1))) ? -1 : size]; \ 79} 80 81#define STRUCT_KFIFO(type, size) \ 82 struct __STRUCT_KFIFO(type, size, 0, type) 83 84#define __STRUCT_KFIFO_PTR(type, recsize, ptrtype) \ 85{ \ 86 __STRUCT_KFIFO_COMMON(type, recsize, ptrtype); \ 87 type buf[0]; \ 88} 89 90#define STRUCT_KFIFO_PTR(type) \ 91 struct __STRUCT_KFIFO_PTR(type, 0, type) 92 93/* 94 * define compatibility "struct kfifo" for dynamic allocated fifos 95 */ 96struct kfifo __STRUCT_KFIFO_PTR(unsigned char, 0, void); 97 98#define STRUCT_KFIFO_REC_1(size) \ 99 struct __STRUCT_KFIFO(unsigned char, size, 1, void) 100 101#define STRUCT_KFIFO_REC_2(size) \ 102 struct __STRUCT_KFIFO(unsigned char, size, 2, void) 103 104/* 105 * define kfifo_rec types 106 */ 107struct kfifo_rec_ptr_1 __STRUCT_KFIFO_PTR(unsigned char, 1, void); 108struct kfifo_rec_ptr_2 __STRUCT_KFIFO_PTR(unsigned char, 2, void); 109 110/* 111 * helper macro to distinguish between real in place fifo where the fifo 112 * array is a part of the structure and the fifo type where the array is 113 * outside of the fifo structure. 114 */ 115#define __is_kfifo_ptr(fifo) (sizeof(*fifo) == sizeof(struct __kfifo)) 116 117/** 118 * DECLARE_KFIFO_PTR - macro to declare a fifo pointer object 119 * @fifo: name of the declared fifo 120 * @type: type of the fifo elements 121 */ 122#define DECLARE_KFIFO_PTR(fifo, type) STRUCT_KFIFO_PTR(type) fifo 123 124/** 125 * DECLARE_KFIFO - macro to declare a fifo object 126 * @fifo: name of the declared fifo 127 * @type: type of the fifo elements 128 * @size: the number of elements in the fifo, this must be a power of 2 129 */ 130#define DECLARE_KFIFO(fifo, type, size) STRUCT_KFIFO(type, size) fifo 131 132/** 133 * INIT_KFIFO - Initialize a fifo declared by DECLARE_KFIFO 134 * @fifo: name of the declared fifo datatype 135 */ 136#define INIT_KFIFO(fifo) \ 137(void)({ \ 138 typeof(&(fifo)) __tmp = &(fifo); \ 139 struct __kfifo *__kfifo = &__tmp->kfifo; \ 140 __kfifo->in = 0; \ 141 __kfifo->out = 0; \ 142 __kfifo->mask = __is_kfifo_ptr(__tmp) ? 0 : ARRAY_SIZE(__tmp->buf) - 1;\ 143 __kfifo->esize = sizeof(*__tmp->buf); \ 144 __kfifo->data = __is_kfifo_ptr(__tmp) ? NULL : __tmp->buf; \ 145}) 146 147/** 148 * DEFINE_KFIFO - macro to define and initialize a fifo 149 * @fifo: name of the declared fifo datatype 150 * @type: type of the fifo elements 151 * @size: the number of elements in the fifo, this must be a power of 2 152 * 153 * Note: the macro can be used for global and local fifo data type variables. 154 */ 155#define DEFINE_KFIFO(fifo, type, size) \ 156 DECLARE_KFIFO(fifo, type, size) = \ 157 (typeof(fifo)) { \ 158 { \ 159 { \ 160 .in = 0, \ 161 .out = 0, \ 162 .mask = __is_kfifo_ptr(&(fifo)) ? \ 163 0 : \ 164 ARRAY_SIZE((fifo).buf) - 1, \ 165 .esize = sizeof(*(fifo).buf), \ 166 .data = __is_kfifo_ptr(&(fifo)) ? \ 167 NULL : \ 168 (fifo).buf, \ 169 } \ 170 } \ 171 } 172 173 174static inline unsigned int __must_check 175__kfifo_must_check_helper(unsigned 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_full - returns true if the fifo is full 257 * @fifo: address of the fifo to be used 258 */ 259#define kfifo_is_full(fifo) \ 260({ \ 261 typeof((fifo) + 1) __tmpq = (fifo); \ 262 kfifo_len(__tmpq) > __tmpq->kfifo.mask; \ 263}) 264 265/** 266 * kfifo_avail - returns the number of unused elements in the fifo 267 * @fifo: address of the fifo to be used 268 */ 269#define kfifo_avail(fifo) \ 270__kfifo_must_check_helper( \ 271({ \ 272 typeof((fifo) + 1) __tmpq = (fifo); \ 273 const size_t __recsize = sizeof(*__tmpq->rectype); \ 274 unsigned int __avail = kfifo_size(__tmpq) - kfifo_len(__tmpq); \ 275 (__recsize) ? ((__avail <= __recsize) ? 0 : \ 276 __kfifo_max_r(__avail - __recsize, __recsize)) : \ 277 __avail; \ 278}) \ 279) 280 281/** 282 * kfifo_skip - skip output data 283 * @fifo: address of the fifo to be used 284 */ 285#define kfifo_skip(fifo) \ 286(void)({ \ 287 typeof((fifo) + 1) __tmp = (fifo); \ 288 const size_t __recsize = sizeof(*__tmp->rectype); \ 289 struct __kfifo *__kfifo = &__tmp->kfifo; \ 290 if (__recsize) \ 291 __kfifo_skip_r(__kfifo, __recsize); \ 292 else \ 293 __kfifo->out++; \ 294}) 295 296/** 297 * kfifo_peek_len - gets the size of the next fifo record 298 * @fifo: address of the fifo to be used 299 * 300 * This function returns the size of the next fifo record in number of bytes. 301 */ 302#define kfifo_peek_len(fifo) \ 303__kfifo_must_check_helper( \ 304({ \ 305 typeof((fifo) + 1) __tmp = (fifo); \ 306 const size_t __recsize = sizeof(*__tmp->rectype); \ 307 struct __kfifo *__kfifo = &__tmp->kfifo; \ 308 (!__recsize) ? kfifo_len(__tmp) * sizeof(*__tmp->type) : \ 309 __kfifo_len_r(__kfifo, __recsize); \ 310}) \ 311) 312 313/** 314 * kfifo_alloc - dynamically allocates a new fifo buffer 315 * @fifo: pointer to the fifo 316 * @size: the number of elements in the fifo, this must be a power of 2 317 * @gfp_mask: get_free_pages mask, passed to kmalloc() 318 * 319 * This macro dynamically allocates a new fifo buffer. 320 * 321 * The numer of elements will be rounded-up to a power of 2. 322 * The fifo will be release with kfifo_free(). 323 * Return 0 if no error, otherwise an error code. 324 */ 325#define kfifo_alloc(fifo, size, gfp_mask) \ 326__kfifo_must_check_helper( \ 327({ \ 328 typeof((fifo) + 1) __tmp = (fifo); \ 329 struct __kfifo *__kfifo = &__tmp->kfifo; \ 330 __is_kfifo_ptr(__tmp) ? \ 331 __kfifo_alloc(__kfifo, size, sizeof(*__tmp->type), gfp_mask) : \ 332 -EINVAL; \ 333}) \ 334) 335 336/** 337 * kfifo_free - frees the fifo 338 * @fifo: the fifo to be freed 339 */ 340#define kfifo_free(fifo) \ 341({ \ 342 typeof((fifo) + 1) __tmp = (fifo); \ 343 struct __kfifo *__kfifo = &__tmp->kfifo; \ 344 if (__is_kfifo_ptr(__tmp)) \ 345 __kfifo_free(__kfifo); \ 346}) 347 348/** 349 * kfifo_init - initialize a fifo using a preallocated buffer 350 * @fifo: the fifo to assign the buffer 351 * @buffer: the preallocated buffer to be used 352 * @size: the size of the internal buffer, this have to be a power of 2 353 * 354 * This macro initialize a fifo using a preallocated buffer. 355 * 356 * The numer of elements will be rounded-up to a power of 2. 357 * Return 0 if no error, otherwise an error code. 358 */ 359#define kfifo_init(fifo, buffer, size) \ 360({ \ 361 typeof((fifo) + 1) __tmp = (fifo); \ 362 struct __kfifo *__kfifo = &__tmp->kfifo; \ 363 __is_kfifo_ptr(__tmp) ? \ 364 __kfifo_init(__kfifo, buffer, size, sizeof(*__tmp->type)) : \ 365 -EINVAL; \ 366}) 367 368/** 369 * kfifo_put - put data into the fifo 370 * @fifo: address of the fifo to be used 371 * @val: the data to be added 372 * 373 * This macro copies the given value into the fifo. 374 * It returns 0 if the fifo was full. Otherwise it returns the number 375 * processed elements. 376 * 377 * Note that with only one concurrent reader and one concurrent 378 * writer, you don't need extra locking to use these macro. 379 */ 380#define kfifo_put(fifo, val) \ 381({ \ 382 typeof((fifo) + 1) __tmp = (fifo); \ 383 typeof((val) + 1) __val = (val); \ 384 unsigned int __ret; \ 385 const size_t __recsize = sizeof(*__tmp->rectype); \ 386 struct __kfifo *__kfifo = &__tmp->kfifo; \ 387 if (0) { \ 388 typeof(__tmp->ptr_const) __dummy __attribute__ ((unused)); \ 389 __dummy = (typeof(__val))NULL; \ 390 } \ 391 if (__recsize) \ 392 __ret = __kfifo_in_r(__kfifo, __val, sizeof(*__val), \ 393 __recsize); \ 394 else { \ 395 __ret = !kfifo_is_full(__tmp); \ 396 if (__ret) { \ 397 (__is_kfifo_ptr(__tmp) ? \ 398 ((typeof(__tmp->type))__kfifo->data) : \ 399 (__tmp->buf) \ 400 )[__kfifo->in & __tmp->kfifo.mask] = \ 401 *(typeof(__tmp->type))__val; \ 402 smp_wmb(); \ 403 __kfifo->in++; \ 404 } \ 405 } \ 406 __ret; \ 407}) 408 409/** 410 * kfifo_get - get data from the fifo 411 * @fifo: address of the fifo to be used 412 * @val: the var where to store the data to be added 413 * 414 * This macro reads the data from the fifo. 415 * It returns 0 if the fifo was empty. Otherwise it returns the number 416 * processed elements. 417 * 418 * Note that with only one concurrent reader and one concurrent 419 * writer, you don't need extra locking to use these macro. 420 */ 421#define kfifo_get(fifo, val) \ 422__kfifo_must_check_helper( \ 423({ \ 424 typeof((fifo) + 1) __tmp = (fifo); \ 425 typeof((val) + 1) __val = (val); \ 426 unsigned int __ret; \ 427 const size_t __recsize = sizeof(*__tmp->rectype); \ 428 struct __kfifo *__kfifo = &__tmp->kfifo; \ 429 if (0) \ 430 __val = (typeof(__tmp->ptr))0; \ 431 if (__recsize) \ 432 __ret = __kfifo_out_r(__kfifo, __val, sizeof(*__val), \ 433 __recsize); \ 434 else { \ 435 __ret = !kfifo_is_empty(__tmp); \ 436 if (__ret) { \ 437 *(typeof(__tmp->type))__val = \ 438 (__is_kfifo_ptr(__tmp) ? \ 439 ((typeof(__tmp->type))__kfifo->data) : \ 440 (__tmp->buf) \ 441 )[__kfifo->out & __tmp->kfifo.mask]; \ 442 smp_wmb(); \ 443 __kfifo->out++; \ 444 } \ 445 } \ 446 __ret; \ 447}) \ 448) 449 450/** 451 * kfifo_peek - get data from the fifo without removing 452 * @fifo: address of the fifo to be used 453 * @val: the var where to store the data to be added 454 * 455 * This reads the data from the fifo without removing it from the fifo. 456 * It returns 0 if the fifo was empty. Otherwise it returns the number 457 * processed elements. 458 * 459 * Note that with only one concurrent reader and one concurrent 460 * writer, you don't need extra locking to use these macro. 461 */ 462#define kfifo_peek(fifo, val) \ 463__kfifo_must_check_helper( \ 464({ \ 465 typeof((fifo) + 1) __tmp = (fifo); \ 466 typeof((val) + 1) __val = (val); \ 467 unsigned int __ret; \ 468 const size_t __recsize = sizeof(*__tmp->rectype); \ 469 struct __kfifo *__kfifo = &__tmp->kfifo; \ 470 if (0) \ 471 __val = (typeof(__tmp->ptr))NULL; \ 472 if (__recsize) \ 473 __ret = __kfifo_out_peek_r(__kfifo, __val, sizeof(*__val), \ 474 __recsize); \ 475 else { \ 476 __ret = !kfifo_is_empty(__tmp); \ 477 if (__ret) { \ 478 *(typeof(__tmp->type))__val = \ 479 (__is_kfifo_ptr(__tmp) ? \ 480 ((typeof(__tmp->type))__kfifo->data) : \ 481 (__tmp->buf) \ 482 )[__kfifo->out & __tmp->kfifo.mask]; \ 483 smp_wmb(); \ 484 } \ 485 } \ 486 __ret; \ 487}) \ 488) 489 490/** 491 * kfifo_in - put data into the fifo 492 * @fifo: address of the fifo to be used 493 * @buf: the data to be added 494 * @n: number of elements to be added 495 * 496 * This macro copies the given buffer into the fifo and returns the 497 * number of copied elements. 498 * 499 * Note that with only one concurrent reader and one concurrent 500 * writer, you don't need extra locking to use these macro. 501 */ 502#define kfifo_in(fifo, buf, n) \ 503({ \ 504 typeof((fifo) + 1) __tmp = (fifo); \ 505 typeof((buf) + 1) __buf = (buf); \ 506 unsigned long __n = (n); \ 507 const size_t __recsize = sizeof(*__tmp->rectype); \ 508 struct __kfifo *__kfifo = &__tmp->kfifo; \ 509 if (0) { \ 510 typeof(__tmp->ptr_const) __dummy __attribute__ ((unused)); \ 511 __dummy = (typeof(__buf))NULL; \ 512 } \ 513 (__recsize) ?\ 514 __kfifo_in_r(__kfifo, __buf, __n, __recsize) : \ 515 __kfifo_in(__kfifo, __buf, __n); \ 516}) 517 518/** 519 * kfifo_in_spinlocked - put data into the fifo using a spinlock for locking 520 * @fifo: address of the fifo to be used 521 * @buf: the data to be added 522 * @n: number of elements to be added 523 * @lock: pointer to the spinlock to use for locking 524 * 525 * This macro copies the given values buffer into the fifo and returns the 526 * number of copied elements. 527 */ 528#define kfifo_in_spinlocked(fifo, buf, n, lock) \ 529({ \ 530 unsigned long __flags; \ 531 unsigned int __ret; \ 532 spin_lock_irqsave(lock, __flags); \ 533 __ret = kfifo_in(fifo, buf, n); \ 534 spin_unlock_irqrestore(lock, __flags); \ 535 __ret; \ 536}) 537 538/* alias for kfifo_in_spinlocked, will be removed in a future release */ 539#define kfifo_in_locked(fifo, buf, n, lock) \ 540 kfifo_in_spinlocked(fifo, buf, n, lock) 541 542/** 543 * kfifo_out - get data from the fifo 544 * @fifo: address of the fifo to be used 545 * @buf: pointer to the storage buffer 546 * @n: max. number of elements to get 547 * 548 * This macro get some data from the fifo and return the numbers of elements 549 * copied. 550 * 551 * Note that with only one concurrent reader and one concurrent 552 * writer, you don't need extra locking to use these macro. 553 */ 554#define kfifo_out(fifo, buf, n) \ 555__kfifo_must_check_helper( \ 556({ \ 557 typeof((fifo) + 1) __tmp = (fifo); \ 558 typeof((buf) + 1) __buf = (buf); \ 559 unsigned long __n = (n); \ 560 const size_t __recsize = sizeof(*__tmp->rectype); \ 561 struct __kfifo *__kfifo = &__tmp->kfifo; \ 562 if (0) { \ 563 typeof(__tmp->ptr) __dummy = NULL; \ 564 __buf = __dummy; \ 565 } \ 566 (__recsize) ?\ 567 __kfifo_out_r(__kfifo, __buf, __n, __recsize) : \ 568 __kfifo_out(__kfifo, __buf, __n); \ 569}) \ 570) 571 572/** 573 * kfifo_out_spinlocked - get data from the fifo using a spinlock for locking 574 * @fifo: address of the fifo to be used 575 * @buf: pointer to the storage buffer 576 * @n: max. number of elements to get 577 * @lock: pointer to the spinlock to use for locking 578 * 579 * This macro get the data from the fifo and return the numbers of elements 580 * copied. 581 */ 582#define kfifo_out_spinlocked(fifo, buf, n, lock) \ 583__kfifo_must_check_helper( \ 584({ \ 585 unsigned long __flags; \ 586 unsigned int __ret; \ 587 spin_lock_irqsave(lock, __flags); \ 588 __ret = kfifo_out(fifo, buf, n); \ 589 spin_unlock_irqrestore(lock, __flags); \ 590 __ret; \ 591}) \ 592) 593 594/* alias for kfifo_out_spinlocked, will be removed in a future release */ 595#define kfifo_out_locked(fifo, buf, n, lock) \ 596 kfifo_out_spinlocked(fifo, buf, n, lock) 597 598/** 599 * kfifo_from_user - puts some data from user space into the fifo 600 * @fifo: address of the fifo to be used 601 * @from: pointer to the data to be added 602 * @len: the length of the data to be added 603 * @copied: pointer to output variable to store the number of copied bytes 604 * 605 * This macro copies at most @len bytes from the @from into the 606 * fifo, depending of the available space and returns -EFAULT/0. 607 * 608 * Note that with only one concurrent reader and one concurrent 609 * writer, you don't need extra locking to use these macro. 610 */ 611#define kfifo_from_user(fifo, from, len, copied) \ 612__kfifo_must_check_helper( \ 613({ \ 614 typeof((fifo) + 1) __tmp = (fifo); \ 615 const void __user *__from = (from); \ 616 unsigned int __len = (len); \ 617 unsigned int *__copied = (copied); \ 618 const size_t __recsize = sizeof(*__tmp->rectype); \ 619 struct __kfifo *__kfifo = &__tmp->kfifo; \ 620 (__recsize) ? \ 621 __kfifo_from_user_r(__kfifo, __from, __len, __copied, __recsize) : \ 622 __kfifo_from_user(__kfifo, __from, __len, __copied); \ 623}) \ 624) 625 626/** 627 * kfifo_to_user - copies data from the fifo into user space 628 * @fifo: address of the fifo to be used 629 * @to: where the data must be copied 630 * @len: the size of the destination buffer 631 * @copied: pointer to output variable to store the number of copied bytes 632 * 633 * This macro copies at most @len bytes from the fifo into the 634 * @to buffer and returns -EFAULT/0. 635 * 636 * Note that with only one concurrent reader and one concurrent 637 * writer, you don't need extra locking to use these macro. 638 */ 639#define kfifo_to_user(fifo, to, len, copied) \ 640__kfifo_must_check_helper( \ 641({ \ 642 typeof((fifo) + 1) __tmp = (fifo); \ 643 void __user *__to = (to); \ 644 unsigned int __len = (len); \ 645 unsigned int *__copied = (copied); \ 646 const size_t __recsize = sizeof(*__tmp->rectype); \ 647 struct __kfifo *__kfifo = &__tmp->kfifo; \ 648 (__recsize) ? \ 649 __kfifo_to_user_r(__kfifo, __to, __len, __copied, __recsize) : \ 650 __kfifo_to_user(__kfifo, __to, __len, __copied); \ 651}) \ 652) 653 654/** 655 * kfifo_dma_in_prepare - setup a scatterlist for DMA input 656 * @fifo: address of the fifo to be used 657 * @sgl: pointer to the scatterlist array 658 * @nents: number of entries in the scatterlist array 659 * @len: number of elements to transfer 660 * 661 * This macro fills a scatterlist for DMA input. 662 * It returns the number entries in the scatterlist array. 663 * 664 * Note that with only one concurrent reader and one concurrent 665 * writer, you don't need extra locking to use these macros. 666 */ 667#define kfifo_dma_in_prepare(fifo, sgl, nents, len) \ 668({ \ 669 typeof((fifo) + 1) __tmp = (fifo); \ 670 struct scatterlist *__sgl = (sgl); \ 671 int __nents = (nents); \ 672 unsigned int __len = (len); \ 673 const size_t __recsize = sizeof(*__tmp->rectype); \ 674 struct __kfifo *__kfifo = &__tmp->kfifo; \ 675 (__recsize) ? \ 676 __kfifo_dma_in_prepare_r(__kfifo, __sgl, __nents, __len, __recsize) : \ 677 __kfifo_dma_in_prepare(__kfifo, __sgl, __nents, __len); \ 678}) 679 680/** 681 * kfifo_dma_in_finish - finish a DMA IN operation 682 * @fifo: address of the fifo to be used 683 * @len: number of bytes to received 684 * 685 * This macro finish a DMA IN operation. The in counter will be updated by 686 * the len parameter. No error checking will be done. 687 * 688 * Note that with only one concurrent reader and one concurrent 689 * writer, you don't need extra locking to use these macros. 690 */ 691#define kfifo_dma_in_finish(fifo, len) \ 692(void)({ \ 693 typeof((fifo) + 1) __tmp = (fifo); \ 694 unsigned int __len = (len); \ 695 const size_t __recsize = sizeof(*__tmp->rectype); \ 696 struct __kfifo *__kfifo = &__tmp->kfifo; \ 697 if (__recsize) \ 698 __kfifo_dma_in_finish_r(__kfifo, __len, __recsize); \ 699 else \ 700 __kfifo->in += __len / sizeof(*__tmp->type); \ 701}) 702 703/** 704 * kfifo_dma_out_prepare - setup a scatterlist for DMA output 705 * @fifo: address of the fifo to be used 706 * @sgl: pointer to the scatterlist array 707 * @nents: number of entries in the scatterlist array 708 * @len: number of elements to transfer 709 * 710 * This macro fills a scatterlist for DMA output which at most @len bytes 711 * to transfer. 712 * It returns the number entries in the scatterlist array. 713 * A zero means there is no space available and the scatterlist is not filled. 714 * 715 * Note that with only one concurrent reader and one concurrent 716 * writer, you don't need extra locking to use these macros. 717 */ 718#define kfifo_dma_out_prepare(fifo, sgl, nents, len) \ 719({ \ 720 typeof((fifo) + 1) __tmp = (fifo); \ 721 struct scatterlist *__sgl = (sgl); \ 722 int __nents = (nents); \ 723 unsigned int __len = (len); \ 724 const size_t __recsize = sizeof(*__tmp->rectype); \ 725 struct __kfifo *__kfifo = &__tmp->kfifo; \ 726 (__recsize) ? \ 727 __kfifo_dma_out_prepare_r(__kfifo, __sgl, __nents, __len, __recsize) : \ 728 __kfifo_dma_out_prepare(__kfifo, __sgl, __nents, __len); \ 729}) 730 731/** 732 * kfifo_dma_out_finish - finish a DMA OUT operation 733 * @fifo: address of the fifo to be used 734 * @len: number of bytes transferd 735 * 736 * This macro finish a DMA OUT operation. The out counter will be updated by 737 * the len parameter. No error checking will be done. 738 * 739 * Note that with only one concurrent reader and one concurrent 740 * writer, you don't need extra locking to use these macros. 741 */ 742#define kfifo_dma_out_finish(fifo, len) \ 743(void)({ \ 744 typeof((fifo) + 1) __tmp = (fifo); \ 745 unsigned int __len = (len); \ 746 const size_t __recsize = sizeof(*__tmp->rectype); \ 747 struct __kfifo *__kfifo = &__tmp->kfifo; \ 748 if (__recsize) \ 749 __kfifo_dma_out_finish_r(__kfifo, __recsize); \ 750 else \ 751 __kfifo->out += __len / sizeof(*__tmp->type); \ 752}) 753 754/** 755 * kfifo_out_peek - gets some data from the fifo 756 * @fifo: address of the fifo to be used 757 * @buf: pointer to the storage buffer 758 * @n: max. number of elements to get 759 * 760 * This macro get the data from the fifo and return the numbers of elements 761 * copied. The data is not removed from the fifo. 762 * 763 * Note that with only one concurrent reader and one concurrent 764 * writer, you don't need extra locking to use these macro. 765 */ 766#define kfifo_out_peek(fifo, buf, n) \ 767__kfifo_must_check_helper( \ 768({ \ 769 typeof((fifo) + 1) __tmp = (fifo); \ 770 typeof((buf) + 1) __buf = (buf); \ 771 unsigned long __n = (n); \ 772 const size_t __recsize = sizeof(*__tmp->rectype); \ 773 struct __kfifo *__kfifo = &__tmp->kfifo; \ 774 if (0) { \ 775 typeof(__tmp->ptr) __dummy __attribute__ ((unused)) = NULL; \ 776 __buf = __dummy; \ 777 } \ 778 (__recsize) ? \ 779 __kfifo_out_peek_r(__kfifo, __buf, __n, __recsize) : \ 780 __kfifo_out_peek(__kfifo, __buf, __n); \ 781}) \ 782) 783 784extern int __kfifo_alloc(struct __kfifo *fifo, unsigned int size, 785 size_t esize, gfp_t gfp_mask); 786 787extern void __kfifo_free(struct __kfifo *fifo); 788 789extern int __kfifo_init(struct __kfifo *fifo, void *buffer, 790 unsigned int size, size_t esize); 791 792extern unsigned int __kfifo_in(struct __kfifo *fifo, 793 const void *buf, unsigned int len); 794 795extern unsigned int __kfifo_out(struct __kfifo *fifo, 796 void *buf, unsigned int len); 797 798extern int __kfifo_from_user(struct __kfifo *fifo, 799 const void __user *from, unsigned long len, unsigned int *copied); 800 801extern int __kfifo_to_user(struct __kfifo *fifo, 802 void __user *to, unsigned long len, unsigned int *copied); 803 804extern unsigned int __kfifo_dma_in_prepare(struct __kfifo *fifo, 805 struct scatterlist *sgl, int nents, unsigned int len); 806 807extern unsigned int __kfifo_dma_out_prepare(struct __kfifo *fifo, 808 struct scatterlist *sgl, int nents, unsigned int len); 809 810extern unsigned int __kfifo_out_peek(struct __kfifo *fifo, 811 void *buf, unsigned int len); 812 813extern unsigned int __kfifo_in_r(struct __kfifo *fifo, 814 const void *buf, unsigned int len, size_t recsize); 815 816extern unsigned int __kfifo_out_r(struct __kfifo *fifo, 817 void *buf, unsigned int len, size_t recsize); 818 819extern int __kfifo_from_user_r(struct __kfifo *fifo, 820 const void __user *from, unsigned long len, unsigned int *copied, 821 size_t recsize); 822 823extern int __kfifo_to_user_r(struct __kfifo *fifo, void __user *to, 824 unsigned long len, unsigned int *copied, size_t recsize); 825 826extern unsigned int __kfifo_dma_in_prepare_r(struct __kfifo *fifo, 827 struct scatterlist *sgl, int nents, unsigned int len, size_t recsize); 828 829extern void __kfifo_dma_in_finish_r(struct __kfifo *fifo, 830 unsigned int len, size_t recsize); 831 832extern unsigned int __kfifo_dma_out_prepare_r(struct __kfifo *fifo, 833 struct scatterlist *sgl, int nents, unsigned int len, size_t recsize); 834 835extern void __kfifo_dma_out_finish_r(struct __kfifo *fifo, size_t recsize); 836 837extern unsigned int __kfifo_len_r(struct __kfifo *fifo, size_t recsize); 838 839extern void __kfifo_skip_r(struct __kfifo *fifo, size_t recsize); 840 841extern unsigned int __kfifo_out_peek_r(struct __kfifo *fifo, 842 void *buf, unsigned int len, size_t recsize); 843 844extern unsigned int __kfifo_max_r(unsigned int len, size_t recsize); 845 846#endif