| blob | fcba6542b8d0132b72be8a93959a60b57c556e38 |
1 /*
2 * linux/fs/pipe.c
3 *
4 * Copyright (C) 1991, 1992, 1999 Linus Torvalds
5 */
7 #include <linux/mm.h>
8 #include <linux/file.h>
9 #include <linux/poll.h>
10 #include <linux/slab.h>
11 #include <linux/module.h>
12 #include <linux/init.h>
13 #include <linux/fs.h>
14 #include <linux/mount.h>
15 #include <linux/pipe_fs_i.h>
16 #include <linux/uio.h>
17 #include <linux/highmem.h>
18 #include <linux/pagemap.h>
19 #include <linux/audit.h>
20 #include <linux/syscalls.h>
22 #include <asm/uaccess.h>
23 #include <asm/ioctls.h>
25 /*
26 * We use a start+len construction, which provides full use of the
27 * allocated memory.
28 * -- Florian Coosmann (FGC)
29 *
30 * Reads with count = 0 should always return 0.
31 * -- Julian Bradfield 1999-06-07.
32 *
33 * FIFOs and Pipes now generate SIGIO for both readers and writers.
34 * -- Jeremy Elson <jelson@circlemud.org> 2001-08-16
35 *
36 * pipe_read & write cleanup
37 * -- Manfred Spraul <manfred@colorfullife.com> 2002-05-09
38 */
40 /* Drop the inode semaphore and wait for a pipe event, atomically */
42 {
45 /*
46 * Pipes are system-local resources, so sleeping on them
47 * is considered a noninteractive wait:
48 */
56 }
58 static int
61 {
66 iov++;
75 }
80 }
82 }
84 static int
87 {
92 iov++;
101 }
106 }
108 }
110 /*
111 * Attempt to pre-fault in the user memory, so we can use atomic copies.
112 * Returns the number of bytes not faulted in.
113 */
115 {
117 iov++;
127 iov++;
128 }
131 }
133 /*
134 * Pre-fault in the user memory, so we can use atomic copies.
135 */
137 {
139 iov++;
147 iov++;
148 }
149 }
153 {
156 /*
157 * If nobody else uses this page, and we don't already have a
158 * temporary page, let's keep track of it as a one-deep
159 * allocation cache. (Otherwise just release our reference to it)
160 */
163 else
165 }
167 /**
168 * generic_pipe_buf_map - virtually map a pipe buffer
169 * @pipe: the pipe that the buffer belongs to
170 * @buf: the buffer that should be mapped
171 * @atomic: whether to use an atomic map
172 *
173 * Description:
174 * This function returns a kernel virtual address mapping for the
175 * pipe_buffer passed in @buf. If @atomic is set, an atomic map is provided
176 * and the caller has to be careful not to fault before calling
177 * the unmap function.
178 *
179 * Note that this function occupies KM_USER0 if @atomic != 0.
180 */
183 {
187 }
190 }
192 /**
193 * generic_pipe_buf_unmap - unmap a previously mapped pipe buffer
194 * @pipe: the pipe that the buffer belongs to
195 * @buf: the buffer that should be unmapped
196 * @map_data: the data that the mapping function returned
197 *
198 * Description:
199 * This function undoes the mapping that ->map() provided.
200 */
203 {
209 }
211 /**
212 * generic_pipe_buf_steal - attempt to take ownership of a &pipe_buffer
213 * @pipe: the pipe that the buffer belongs to
214 * @buf: the buffer to attempt to steal
215 *
216 * Description:
217 * This function attempts to steal the &struct page attached to
218 * @buf. If successful, this function returns 0 and returns with
219 * the page locked. The caller may then reuse the page for whatever
220 * he wishes; the typical use is insertion into a different file
221 * page cache.
222 */
225 {
228 /*
229 * A reference of one is golden, that means that the owner of this
230 * page is the only one holding a reference to it. lock the page
231 * and return OK.
232 */
236 }
239 }
241 /**
242 * generic_pipe_buf_get - get a reference to a &struct pipe_buffer
243 * @pipe: the pipe that the buffer belongs to
244 * @buf: the buffer to get a reference to
245 *
246 * Description:
247 * This function grabs an extra reference to @buf. It's used in
248 * in the tee() system call, when we duplicate the buffers in one
249 * pipe into another.
250 */
252 {
254 }
256 /**
257 * generic_pipe_buf_confirm - verify contents of the pipe buffer
258 * @info: the pipe that the buffer belongs to
259 * @buf: the buffer to confirm
260 *
261 * Description:
262 * This function does nothing, because the generic pipe code uses
263 * pages that are always good when inserted into the pipe.
264 */
267 {
269 }
279 };
281 static ssize_t
284 {
289 ssize_t ret;
294 /* Null read succeeds. */
320 }
323 redo:
328 /*
329 * Just retry with the slow path if we failed.
330 */
334 }
338 }
349 }
353 }
359 /* syscall merging: Usually we must not sleep
360 * if O_NONBLOCK is set, or if we got some data.
361 * But if a writer sleeps in kernel space, then
362 * we can wait for that data without violating POSIX.
363 */
369 }
370 }
375 }
379 }
381 }
384 /* Signal writers asynchronously that there is more room. */
388 }
392 }
394 static ssize_t
397 {
401 ssize_t ret;
405 ssize_t chars;
408 /* Null write succeeds. */
421 }
423 /* We try to merge small writes */
441 redo1:
452 }
454 }
460 }
461 }
471 }
485 }
487 }
488 /* Always wake up, even if the copy fails. Otherwise
489 * we lock up (O_NONBLOCK-)readers that sleep due to
490 * syscall merging.
491 * FIXME! Is this really true?
492 */
499 redo2:
502 else
506 atomic);
509 else
516 }
520 }
523 /* Insert it into the buffer array */
534 }
541 }
546 }
551 }
555 }
556 out:
561 }
565 }
567 static ssize_t
569 {
571 }
573 static ssize_t
576 {
578 }
581 {
596 }
602 }
603 }
605 /* No kernel lock held - fine */
606 static unsigned int
608 {
616 /* Reading only -- no need for acquiring the semaphore. */
623 }
627 /*
628 * Most Unices do not set POLLERR for FIFOs but on Linux they
629 * behave exactly like pipes for poll().
630 */
633 }
636 }
638 static int
640 {
654 }
658 }
660 static int
662 {
674 }
677 static int
679 {
691 }
694 static int
696 {
714 }
717 static int
719 {
722 }
724 static int
726 {
729 }
731 static int
733 {
740 }
742 static int
744 {
745 /* We could have perhaps used atomic_t, but this and friends
746 below are the only places. So it doesn't seem worthwhile. */
752 }
754 static int
756 {
762 }
764 static int
766 {
775 }
777 /*
778 * The file_operations structs are not static because they
779 * are also used in linux/fs/fifo.c to do operations on FIFOs.
780 *
781 * Pipes reuse fifos' file_operations structs.
782 */
793 };
805 };
818 };
821 {
829 }
832 }
835 {
842 }
846 }
849 {
852 }
856 {
857 /*
858 * At creation time, we pretended this dentry was hashed
859 * (by clearing DCACHE_UNHASHED bit in d_flags)
860 * At delete time, we restore the truth : not hashed.
861 * (so that dput() can proceed correctly)
862 */
865 }
867 /*
868 * pipefs_dname() is called from d_path().
869 */
871 {
874 }
879 };
882 {
897 /*
898 * Mark the inode dirty from the very beginning,
899 * that way it will never be moved to the dirty
900 * list because "mark_inode_dirty()" will think
901 * that it already _is_ on the dirty list.
902 */
911 fail_iput:
914 fail_inode:
916 }
919 {
937 /*
938 * We dont want to publish this dentry into global dentry hash table.
939 * We pretend dentry is already hashed, by unsetting DCACHE_UNHASHED
940 * This permits a working /proc/$pid/fd/XXX on pipes
941 */
956 err_dentry:
961 err_inode:
964 err:
966 }
969 {
973 }
976 {
981 /* Grab pipe from the writer */
993 }
996 {
1033 err_fdw:
1035 err_fdr:
1037 err_read_pipe:
1040 err_write_pipe:
1043 }
1046 {
1048 }
1050 /*
1051 * sys_pipe() is the normal C calling standard for creating
1052 * a pipe. It's not the way Unix traditionally does this, though.
1053 */
1055 {
1065 }
1066 }
1068 }
1071 {
1073 }
1075 /*
1076 * pipefs should _never_ be mounted by userland - too much of security hassle,
1077 * no real gain from having the whole whorehouse mounted. So we don't need
1078 * any operations on the root directory. However, we need a non-trivial
1079 * d_name - pipe: will go nicely and kill the special-casing in procfs.
1080 */
1084 {
1086 }
1092 };
1095 {
1103 }
1104 }
1106 }
1109 {
1112 }