| blob | 4eed2f6c8eeb812921a3a047d996da6cb77742f7 |
1 /*
2 * "splice": joining two ropes together by interweaving their strands.
3 *
4 * This is the "extended pipe" functionality, where a pipe is used as
5 * an arbitrary in-memory buffer. Think of a pipe as a small kernel
6 * buffer that you can use to transfer data from one end to the other.
7 *
8 * The traditional unix read/write is extended with a "splice()" operation
9 * that transfers data buffers to or from a pipe buffer.
10 *
11 * Named by Larry McVoy, original implementation from Linus, extended by
12 * Jens to support splicing to files, network, direct splicing, etc and
13 * fixing lots of bugs.
14 *
15 * Copyright (C) 2005-2006 Jens Axboe <axboe@suse.de>
16 * Copyright (C) 2005-2006 Linus Torvalds <torvalds@osdl.org>
17 * Copyright (C) 2006 Ingo Molnar <mingo@elte.hu>
18 *
19 */
20 #include <linux/fs.h>
21 #include <linux/file.h>
22 #include <linux/pagemap.h>
23 #include <linux/pipe_fs_i.h>
24 #include <linux/mm_inline.h>
25 #include <linux/swap.h>
26 #include <linux/writeback.h>
27 #include <linux/buffer_head.h>
28 #include <linux/module.h>
29 #include <linux/syscalls.h>
30 #include <linux/uio.h>
35 };
37 /*
38 * Passed to splice_to_pipe
39 */
46 };
48 /*
49 * Attempt to steal a page from a pipe buffer. This should perhaps go into
50 * a vm helper function, it's already simplified quite a bit by the
51 * addition of remove_mapping(). If success is returned, the caller may
52 * attempt to reuse this page for another destination.
53 */
56 {
66 /*
67 * At least for ext2 with nobh option, we need to wait on
68 * writeback completing on this page, since we'll remove it
69 * from the pagecache. Otherwise truncate wont wait on the
70 * page, allowing the disk blocks to be reused by someone else
71 * before we actually wrote our data to them. fs corruption
72 * ensues.
73 */
79 /*
80 * If we succeeded in removing the mapping, set LRU flag
81 * and return good.
82 */
86 }
87 }
89 /*
90 * Raced with truncate or failed to remove page from current
91 * address space, unlock and return failure.
92 */
95 }
99 {
102 }
106 {
113 /*
114 * Page got truncated/unhashed. This will cause a 0-byte
115 * splice, if this is the first page.
116 */
120 }
122 /*
123 * Uh oh, read-error from disk.
124 */
128 }
130 /*
131 * Page is ok afterall, we are done.
132 */
134 }
137 error:
140 }
150 };
154 {
160 }
170 };
172 /*
173 * Pipe output worker. This sets up our pipe format with the page cache
174 * pipe buffer operations. Otherwise very similar to the regular pipe_writev().
175 */
178 {
194 }
208 page_nr++;
220 }
226 }
232 }
240 }
245 }
255 }
261 }
263 static int
267 {
274 loff_t isize;
282 };
291 /*
292 * Initiate read-ahead on this page range. however, don't call into
293 * read-ahead if this is a non-zero offset (we are likely doing small
294 * chunk splice and the page is already there) for a single page.
295 */
299 /*
300 * Now fill in the holes:
301 */
305 /*
306 * Lookup the (hopefully) full range of pages we need.
307 */
310 /*
311 * If find_get_pages_contig() returned fewer pages than we needed,
312 * allocate the rest.
313 */
316 /*
317 * Page could be there, find_get_pages_contig() breaks on
318 * the first hole.
319 */
322 /*
323 * Make sure the read-ahead engine is notified
324 * about this failure.
325 */
328 /*
329 * page didn't exist, allocate one.
330 */
342 }
343 /*
344 * add_to_page_cache() locks the page, unlock it
345 * to avoid convoluting the logic below even more.
346 */
348 }
351 index++;
352 }
354 /*
355 * Now loop over the map and see if we need to start IO on any
356 * pages, fill in the partial map, etc.
357 */
367 /*
368 * this_len is the max we'll use from this page
369 */
373 /*
374 * If the page isn't uptodate, we may need to start io on it
375 */
377 /*
378 * If in nonblock mode then dont block on waiting
379 * for an in-flight io page
380 */
386 /*
387 * page was truncated, stop here. if this isn't the
388 * first page, we'll just complete what we already
389 * added
390 */
394 }
395 /*
396 * page was already under io and is now done, great
397 */
401 }
403 /*
404 * need to read in the page
405 */
408 /*
409 * We really should re-lookup the page here,
410 * but it complicates things a lot. Instead
411 * lets just do what we already stored, and
412 * we'll get it the next time we are called.
413 */
418 }
420 /*
421 * i_size must be checked after ->readpage().
422 */
428 /*
429 * if this is the last page, see if we need to shrink
430 * the length and stop
431 */
436 /*
437 * force quit after adding this page
438 */
442 }
443 }
444 fill_it:
451 index++;
452 }
454 /*
455 * Release any pages at the end, if we quit early. 'i' is how far
456 * we got, 'nr_pages' is how many pages are in the map.
457 */
465 }
467 /**
468 * generic_file_splice_read - splice data from file to a pipe
469 * @in: file to splice from
470 * @pipe: pipe to splice to
471 * @len: number of bytes to splice
472 * @flags: splice modifier flags
473 *
474 * Will read pages from given file and fill them into a pipe.
475 */
479 {
480 ssize_t spliced;
497 }
498 }
503 }
509 }
513 /*
514 * Send 'sd->len' bytes to socket from 'sd->file' at position 'sd->pos'
515 * using sendpage(). Return the number of bytes sent.
516 */
519 {
530 }
533 }
535 /*
536 * This is a little more tricky than the file -> pipe splicing. There are
537 * basically three cases:
538 *
539 * - Destination page already exists in the address space and there
540 * are users of it. For that case we have no other option that
541 * copying the data. Tough luck.
542 * - Destination page already exists in the address space, but there
543 * are no users of it. Make sure it's uptodate, then drop it. Fall
544 * through to last case.
545 * - Destination page does not exist, we can add the pipe page to
546 * the page cache and avoid the copy.
547 *
548 * If asked to move pages to the output file (SPLICE_F_MOVE is set in
549 * sd->flags), we attempt to migrate pages from the pipe to the output
550 * file address space page cache. This is possible if no one else has
551 * the pipe page referenced outside of the pipe and page cache. If
552 * SPLICE_F_MOVE isn't set, or we cannot move the page, we simply create
553 * a new page in the output file page cache and fill/dirty that.
554 */
557 {
563 pgoff_t index;
566 /*
567 * make sure the data in this buffer is uptodate
568 */
580 /*
581 * Reuse buf page, if SPLICE_F_MOVE is set and we are doing a full
582 * page.
583 */
585 /*
586 * If steal succeeds, buf->page is now pruned from the
587 * pagecache and we can reuse it. The page will also be
588 * locked on successful return.
589 */
597 }
604 find_page:
612 /*
613 * This will also lock the page
614 */
616 gfp_mask);
619 }
621 /*
622 * We get here with the page locked. If the page is also
623 * uptodate, we don't need to do more. If it isn't, we
624 * may need to bring it in if we are not going to overwrite
625 * the full page.
626 */
636 /*
637 * Page got invalidated, repeat.
638 */
643 }
646 }
649 }
650 }
662 /*
663 * prepare_write() may have instantiated a few blocks
664 * outside i_size. Trim these off again.
665 */
670 }
673 /*
674 * Careful, ->map() uses KM_USER0!
675 */
683 }
687 /*
688 * Return the number of bytes written and mark page as
689 * accessed, we are now done!
690 */
697 }
698 out:
701 out_ret:
703 }
705 /*
706 * Pipe input worker. Most of this logic works like a regular pipe, the
707 * key here is the 'actor' worker passed in that actually moves the data
708 * to the wanted destination. See pipe_to_file/pipe_to_sendpage above.
709 */
713 {
743 }
762 }
766 }
775 }
781 }
787 }
795 }
798 }
808 }
811 }
813 /**
814 * generic_file_splice_write - splice data from a pipe to a file
815 * @pipe: pipe info
816 * @out: file to write to
817 * @len: number of bytes to splice
818 * @flags: splice modifier flags
819 *
820 * Will either move or copy pages (determined by @flags options) from
821 * the given pipe inode to the given file.
822 *
823 */
824 ssize_t
827 {
829 ssize_t ret;
837 /*
838 * If file or inode is SYNC and we actually wrote some data,
839 * sync it.
840 */
851 }
852 }
855 }
859 /**
860 * generic_splice_sendpage - splice data from a pipe to a socket
861 * @inode: pipe inode
862 * @out: socket to write to
863 * @len: number of bytes to splice
864 * @flags: splice modifier flags
865 *
866 * Will send @len bytes from the pipe to a network socket. No data copying
867 * is involved.
868 *
869 */
872 {
874 }
878 /*
879 * Attempt to initiate a splice from pipe to file.
880 */
883 {
897 }
899 /*
900 * Attempt to initiate a splice from a file to a pipe.
901 */
905 {
928 }
932 {
935 loff_t out_off;
936 umode_t i_mode;
939 /*
940 * We require the input being a regular file, as we don't want to
941 * randomly drop data for eg socket -> socket splicing. Use the
942 * piped splicing for that!
943 */
948 /*
949 * neither in nor out is a pipe, setup an internal pipe attached to
950 * 'out' and transfer the wanted data from 'in' to 'out' through that
951 */
958 /*
959 * We don't have an immediate reader, but we'll read the stuff
960 * out of the pipe right after the splice_to_pipe(). So set
961 * PIPE_READERS appropriately.
962 */
966 }
968 /*
969 * Do the splice.
970 */
978 /*
979 * Do at most PIPE_BUFFERS pages worth of transfer:
980 */
989 /*
990 * NOTE: nonblocking mode only applies to the input. We
991 * must not do the output in nonblocking mode as then we
992 * could get stuck data in the internal pipe:
993 */
1002 /*
1003 * In nonblocking mode, if we got back a short read then
1004 * that was due to either an IO error or due to the
1005 * pagecache entry not being there. In the IO error case
1006 * the _next_ splice attempt will produce a clean IO error
1007 * return value (not a short read), so in both cases it's
1008 * correct to break out of the loop here:
1009 */
1012 }
1018 out_release:
1019 /*
1020 * If we did an incomplete transfer we must release
1021 * the pipe buffers in question:
1022 */
1029 }
1030 }
1033 /*
1034 * If we transferred some data, return the number of bytes:
1035 */
1040 }
1044 /*
1045 * Determine where to splice to/from.
1046 */
1050 {
1074 }
1095 }
1098 }
1100 /*
1101 * Map an iov into an array of pages and offset/length tupples. With the
1102 * partial_page structure, we can map several non-contiguous ranges into
1103 * our ones pages[] map instead of splitting that operation into pieces.
1104 * Could easily be exported as a generic helper for other users, in which
1105 * case one would probably want to add a 'max_nr_pages' parameter as well.
1106 */
1110 {
1113 /*
1114 * It's ok to take the mmap_sem for reading, even
1115 * across a "get_user()".
1116 */
1125 /*
1126 * Get user address base and length for this iovec.
1127 */
1135 /*
1136 * Sanity check this iovec. 0 read succeeds.
1137 */
1144 /*
1145 * Get this base offset and number of pages, then map
1146 * in the user pages.
1147 */
1150 /*
1151 * If asked for alignment, the offset must be zero and the
1152 * length a multiple of the PAGE_SIZE.
1153 */
1169 /*
1170 * Fill this contiguous range into the partial page map.
1171 */
1180 buffers++;
1181 }
1183 /*
1184 * We didn't complete this iov, stop here since it probably
1185 * means we have to move some of this into a pipe to
1186 * be able to continue.
1187 */
1191 /*
1192 * Don't continue if we mapped fewer pages than we asked for,
1193 * or if we mapped the max number of pages that we have
1194 * room for.
1195 */
1199 nr_vecs--;
1200 iov++;
1201 }
1209 }
1211 /*
1212 * vmsplice splices a user address range into a pipe. It can be thought of
1213 * as splice-from-memory, where the regular splice is splice-from-file (or
1214 * to file). In both cases the output is a pipe, naturally.
1215 *
1216 * Note that vmsplice only supports splicing _from_ user memory to a pipe,
1217 * not the other way around. Splicing from user memory is a simple operation
1218 * that can be supported without any funky alignment restrictions or nasty
1219 * vm tricks. We simply map in the user memory and fill them into a pipe.
1220 * The reverse isn't quite as easy, though. There are two possible solutions
1221 * for that:
1222 *
1223 * - memcpy() the data internally, at which point we might as well just
1224 * do a regular read() on the buffer anyway.
1225 * - Lots of nasty vm tricks, that are neither fast nor flexible (it
1226 * has restriction limitations on both ends of the pipe).
1227 *
1228 * Alas, it isn't here.
1229 *
1230 */
1233 {
1242 };
1257 }
1261 {
1273 }
1276 }
1281 {
1300 }
1301 }
1304 }
1307 }
1309 /*
1310 * Make sure there's data to read. Wait for input if we can, otherwise
1311 * return an appropriate error.
1312 */
1314 {
1317 /*
1318 * Check ->nrbufs without the inode lock first. This function
1319 * is speculative anyways, so missing one is ok.
1320 */
1331 }
1338 }
1339 }
1341 }
1345 }
1347 /*
1348 * Make sure there's writeable room. Wait for room if we can, otherwise
1349 * return an appropriate error.
1350 */
1352 {
1355 /*
1356 * Check ->nrbufs without the inode lock first. This function
1357 * is speculative anyways, so missing one is ok.
1358 */
1370 }
1374 }
1378 }
1382 }
1386 }
1388 /*
1389 * Link contents of ipipe to opipe.
1390 */
1394 {
1398 /*
1399 * Potential ABBA deadlock, work around it by ordering lock
1400 * grabbing by inode address. Otherwise two different processes
1401 * could deadlock (one doing tee from A -> B, the other from B -> A).
1402 */
1409 }
1417 }
1419 /*
1420 * If we have iterated all input buffers or ran out of
1421 * output room, break.
1422 */
1429 /*
1430 * Get a reference to this pipe buffer,
1431 * so we can copy the contents over.
1432 */
1438 /*
1439 * Don't inherit the gift flag, we need to
1440 * prevent multiple steals of this page.
1441 */
1450 i++;
1456 /*
1457 * If we put data in the output pipe, wakeup any potential readers.
1458 */
1464 }
1467 }
1469 /*
1470 * This is a tee(1) implementation that works on pipes. It doesn't copy
1471 * any data, it simply references the 'in' pages on the 'out' pipe.
1472 * The 'flags' used are the SPLICE_F_* variants, currently the only
1473 * applicable one is SPLICE_F_NONBLOCK.
1474 */
1477 {
1482 /*
1483 * Duplicate the contents of ipipe to opipe without actually
1484 * copying the data.
1485 */
1487 /*
1488 * Keep going, unless we encounter an error. The ipipe/opipe
1489 * ordering doesn't really matter.
1490 */
1498 }
1499 }
1500 }
1503 }
1506 {
1524 }
1525 }
1527 }
1530 }