// SPDX-License-Identifier: GPL-2.0-or-later /* Network filesystem high-level buffered read support. * * Copyright (C) 2021 Red Hat, Inc. All Rights Reserved. * Written by David Howells (dhowells@redhat.com) */ #include #include #include "internal.h" static void netfs_cache_expand_readahead(struct netfs_io_request *rreq, unsigned long long *_start, unsigned long long *_len, unsigned long long i_size) { struct netfs_cache_resources *cres = &rreq->cache_resources; if (cres->ops && cres->ops->expand_readahead) cres->ops->expand_readahead(cres, _start, _len, i_size); } static void netfs_rreq_expand(struct netfs_io_request *rreq, struct readahead_control *ractl) { /* Give the cache a chance to change the request parameters. The * resultant request must contain the original region. */ netfs_cache_expand_readahead(rreq, &rreq->start, &rreq->len, rreq->i_size); /* Give the netfs a chance to change the request parameters. The * resultant request must contain the original region. */ if (rreq->netfs_ops->expand_readahead) rreq->netfs_ops->expand_readahead(rreq); /* Expand the request if the cache wants it to start earlier. Note * that the expansion may get further extended if the VM wishes to * insert THPs and the preferred start and/or end wind up in the middle * of THPs. * * If this is the case, however, the THP size should be an integer * multiple of the cache granule size, so we get a whole number of * granules to deal with. */ if (rreq->start != readahead_pos(ractl) || rreq->len != readahead_length(ractl)) { readahead_expand(ractl, rreq->start, rreq->len); rreq->start = readahead_pos(ractl); rreq->len = readahead_length(ractl); trace_netfs_read(rreq, readahead_pos(ractl), readahead_length(ractl), netfs_read_trace_expanded); } } /* * Begin an operation, and fetch the stored zero point value from the cookie if * available. */ static int netfs_begin_cache_read(struct netfs_io_request *rreq, struct netfs_inode *ctx) { return fscache_begin_read_operation(&rreq->cache_resources, netfs_i_cookie(ctx)); } /* * netfs_prepare_read_iterator - Prepare the subreq iterator for I/O * @subreq: The subrequest to be set up * * Prepare the I/O iterator representing the read buffer on a subrequest for * the filesystem to use for I/O (it can be passed directly to a socket). This * is intended to be called from the ->issue_read() method once the filesystem * has trimmed the request to the size it wants. * * Returns the limited size if successful and -ENOMEM if insufficient memory * available. * * [!] NOTE: This must be run in the same thread as ->issue_read() was called * in as we access the readahead_control struct. */ static ssize_t netfs_prepare_read_iterator(struct netfs_io_subrequest *subreq) { struct netfs_io_request *rreq = subreq->rreq; size_t rsize = subreq->len; if (subreq->source == NETFS_DOWNLOAD_FROM_SERVER) rsize = umin(rsize, rreq->io_streams[0].sreq_max_len); if (rreq->ractl) { /* If we don't have sufficient folios in the rolling buffer, * extract a folioq's worth from the readahead region at a time * into the buffer. Note that this acquires a ref on each page * that we will need to release later - but we don't want to do * that until after we've started the I/O. */ struct folio_batch put_batch; folio_batch_init(&put_batch); while (rreq->submitted < subreq->start + rsize) { ssize_t added; added = rolling_buffer_load_from_ra(&rreq->buffer, rreq->ractl, &put_batch); if (added < 0) return added; rreq->submitted += added; } folio_batch_release(&put_batch); } subreq->len = rsize; if (unlikely(rreq->io_streams[0].sreq_max_segs)) { size_t limit = netfs_limit_iter(&rreq->buffer.iter, 0, rsize, rreq->io_streams[0].sreq_max_segs); if (limit < rsize) { subreq->len = limit; trace_netfs_sreq(subreq, netfs_sreq_trace_limited); } } subreq->io_iter = rreq->buffer.iter; iov_iter_truncate(&subreq->io_iter, subreq->len); rolling_buffer_advance(&rreq->buffer, subreq->len); return subreq->len; } static enum netfs_io_source netfs_cache_prepare_read(struct netfs_io_request *rreq, struct netfs_io_subrequest *subreq, loff_t i_size) { struct netfs_cache_resources *cres = &rreq->cache_resources; enum netfs_io_source source; if (!cres->ops) return NETFS_DOWNLOAD_FROM_SERVER; source = cres->ops->prepare_read(subreq, i_size); trace_netfs_sreq(subreq, netfs_sreq_trace_prepare); return source; } /* * Issue a read against the cache. * - Eats the caller's ref on subreq. */ static void netfs_read_cache_to_pagecache(struct netfs_io_request *rreq, struct netfs_io_subrequest *subreq) { struct netfs_cache_resources *cres = &rreq->cache_resources; netfs_stat(&netfs_n_rh_read); cres->ops->read(cres, subreq->start, &subreq->io_iter, NETFS_READ_HOLE_IGNORE, netfs_cache_read_terminated, subreq); } static void netfs_issue_read(struct netfs_io_request *rreq, struct netfs_io_subrequest *subreq) { struct netfs_io_stream *stream = &rreq->io_streams[0]; __set_bit(NETFS_SREQ_IN_PROGRESS, &subreq->flags); /* We add to the end of the list whilst the collector may be walking * the list. The collector only goes nextwards and uses the lock to * remove entries off of the front. */ spin_lock(&rreq->lock); list_add_tail(&subreq->rreq_link, &stream->subrequests); if (list_is_first(&subreq->rreq_link, &stream->subrequests)) { stream->front = subreq; if (!stream->active) { stream->collected_to = stream->front->start; /* Store list pointers before active flag */ smp_store_release(&stream->active, true); } } spin_unlock(&rreq->lock); switch (subreq->source) { case NETFS_DOWNLOAD_FROM_SERVER: rreq->netfs_ops->issue_read(subreq); break; case NETFS_READ_FROM_CACHE: netfs_read_cache_to_pagecache(rreq, subreq); break; default: __set_bit(NETFS_SREQ_CLEAR_TAIL, &subreq->flags); subreq->error = 0; iov_iter_zero(subreq->len, &subreq->io_iter); subreq->transferred = subreq->len; netfs_read_subreq_terminated(subreq); break; } } /* * Perform a read to the pagecache from a series of sources of different types, * slicing up the region to be read according to available cache blocks and * network rsize. */ static void netfs_read_to_pagecache(struct netfs_io_request *rreq) { struct netfs_inode *ictx = netfs_inode(rreq->inode); unsigned long long start = rreq->start; ssize_t size = rreq->len; int ret = 0; do { struct netfs_io_subrequest *subreq; enum netfs_io_source source = NETFS_SOURCE_UNKNOWN; ssize_t slice; subreq = netfs_alloc_subrequest(rreq); if (!subreq) { ret = -ENOMEM; break; } subreq->start = start; subreq->len = size; source = netfs_cache_prepare_read(rreq, subreq, rreq->i_size); subreq->source = source; if (source == NETFS_DOWNLOAD_FROM_SERVER) { unsigned long long zp = umin(ictx->zero_point, rreq->i_size); size_t len = subreq->len; if (unlikely(rreq->origin == NETFS_READ_SINGLE)) zp = rreq->i_size; if (subreq->start >= zp) { subreq->source = source = NETFS_FILL_WITH_ZEROES; goto fill_with_zeroes; } if (len > zp - subreq->start) len = zp - subreq->start; if (len == 0) { pr_err("ZERO-LEN READ: R=%08x[%x] l=%zx/%zx s=%llx z=%llx i=%llx", rreq->debug_id, subreq->debug_index, subreq->len, size, subreq->start, ictx->zero_point, rreq->i_size); break; } subreq->len = len; netfs_stat(&netfs_n_rh_download); if (rreq->netfs_ops->prepare_read) { ret = rreq->netfs_ops->prepare_read(subreq); if (ret < 0) { subreq->error = ret; /* Not queued - release both refs. */ netfs_put_subrequest(subreq, false, netfs_sreq_trace_put_cancel); netfs_put_subrequest(subreq, false, netfs_sreq_trace_put_cancel); break; } trace_netfs_sreq(subreq, netfs_sreq_trace_prepare); } goto issue; } fill_with_zeroes: if (source == NETFS_FILL_WITH_ZEROES) { subreq->source = NETFS_FILL_WITH_ZEROES; trace_netfs_sreq(subreq, netfs_sreq_trace_submit); netfs_stat(&netfs_n_rh_zero); goto issue; } if (source == NETFS_READ_FROM_CACHE) { trace_netfs_sreq(subreq, netfs_sreq_trace_submit); goto issue; } pr_err("Unexpected read source %u\n", source); WARN_ON_ONCE(1); break; issue: slice = netfs_prepare_read_iterator(subreq); if (slice < 0) { ret = slice; subreq->error = ret; trace_netfs_sreq(subreq, netfs_sreq_trace_cancel); /* Not queued - release both refs. */ netfs_put_subrequest(subreq, false, netfs_sreq_trace_put_cancel); netfs_put_subrequest(subreq, false, netfs_sreq_trace_put_cancel); break; } size -= slice; start += slice; if (size <= 0) { smp_wmb(); /* Write lists before ALL_QUEUED. */ set_bit(NETFS_RREQ_ALL_QUEUED, &rreq->flags); } netfs_issue_read(rreq, subreq); cond_resched(); } while (size > 0); if (unlikely(size > 0)) { smp_wmb(); /* Write lists before ALL_QUEUED. */ set_bit(NETFS_RREQ_ALL_QUEUED, &rreq->flags); netfs_wake_read_collector(rreq); } /* Defer error return as we may need to wait for outstanding I/O. */ cmpxchg(&rreq->error, 0, ret); } /** * netfs_readahead - Helper to manage a read request * @ractl: The description of the readahead request * * Fulfil a readahead request by drawing data from the cache if possible, or * the netfs if not. Space beyond the EOF is zero-filled. Multiple I/O * requests from different sources will get munged together. If necessary, the * readahead window can be expanded in either direction to a more convenient * alighment for RPC efficiency or to make storage in the cache feasible. * * The calling netfs must initialise a netfs context contiguous to the vfs * inode before calling this. * * This is usable whether or not caching is enabled. */ void netfs_readahead(struct readahead_control *ractl) { struct netfs_io_request *rreq; struct netfs_inode *ictx = netfs_inode(ractl->mapping->host); unsigned long long start = readahead_pos(ractl); size_t size = readahead_length(ractl); int ret; rreq = netfs_alloc_request(ractl->mapping, ractl->file, start, size, NETFS_READAHEAD); if (IS_ERR(rreq)) return; __set_bit(NETFS_RREQ_OFFLOAD_COLLECTION, &rreq->flags); ret = netfs_begin_cache_read(rreq, ictx); if (ret == -ENOMEM || ret == -EINTR || ret == -ERESTARTSYS) goto cleanup_free; netfs_stat(&netfs_n_rh_readahead); trace_netfs_read(rreq, readahead_pos(ractl), readahead_length(ractl), netfs_read_trace_readahead); netfs_rreq_expand(rreq, ractl); rreq->ractl = ractl; rreq->submitted = rreq->start; if (rolling_buffer_init(&rreq->buffer, rreq->debug_id, ITER_DEST) < 0) goto cleanup_free; netfs_read_to_pagecache(rreq); netfs_put_request(rreq, true, netfs_rreq_trace_put_return); return; cleanup_free: netfs_put_request(rreq, false, netfs_rreq_trace_put_failed); return; } EXPORT_SYMBOL(netfs_readahead); /* * Create a rolling buffer with a single occupying folio. */ static int netfs_create_singular_buffer(struct netfs_io_request *rreq, struct folio *folio, unsigned int rollbuf_flags) { ssize_t added; if (rolling_buffer_init(&rreq->buffer, rreq->debug_id, ITER_DEST) < 0) return -ENOMEM; added = rolling_buffer_append(&rreq->buffer, folio, rollbuf_flags); if (added < 0) return added; rreq->submitted = rreq->start + added; rreq->ractl = (struct readahead_control *)1UL; return 0; } /* * Read into gaps in a folio partially filled by a streaming write. */ static int netfs_read_gaps(struct file *file, struct folio *folio) { struct netfs_io_request *rreq; struct address_space *mapping = folio->mapping; struct netfs_folio *finfo = netfs_folio_info(folio); struct netfs_inode *ctx = netfs_inode(mapping->host); struct folio *sink = NULL; struct bio_vec *bvec; unsigned int from = finfo->dirty_offset; unsigned int to = from + finfo->dirty_len; unsigned int off = 0, i = 0; size_t flen = folio_size(folio); size_t nr_bvec = flen / PAGE_SIZE + 2; size_t part; int ret; _enter("%lx", folio->index); rreq = netfs_alloc_request(mapping, file, folio_pos(folio), flen, NETFS_READ_GAPS); if (IS_ERR(rreq)) { ret = PTR_ERR(rreq); goto alloc_error; } ret = netfs_begin_cache_read(rreq, ctx); if (ret == -ENOMEM || ret == -EINTR || ret == -ERESTARTSYS) goto discard; netfs_stat(&netfs_n_rh_read_folio); trace_netfs_read(rreq, rreq->start, rreq->len, netfs_read_trace_read_gaps); /* Fiddle the buffer so that a gap at the beginning and/or a gap at the * end get copied to, but the middle is discarded. */ ret = -ENOMEM; bvec = kmalloc_array(nr_bvec, sizeof(*bvec), GFP_KERNEL); if (!bvec) goto discard; sink = folio_alloc(GFP_KERNEL, 0); if (!sink) { kfree(bvec); goto discard; } trace_netfs_folio(folio, netfs_folio_trace_read_gaps); rreq->direct_bv = bvec; rreq->direct_bv_count = nr_bvec; if (from > 0) { bvec_set_folio(&bvec[i++], folio, from, 0); off = from; } while (off < to) { part = min_t(size_t, to - off, PAGE_SIZE); bvec_set_folio(&bvec[i++], sink, part, 0); off += part; } if (to < flen) bvec_set_folio(&bvec[i++], folio, flen - to, to); iov_iter_bvec(&rreq->buffer.iter, ITER_DEST, bvec, i, rreq->len); rreq->submitted = rreq->start + flen; netfs_read_to_pagecache(rreq); if (sink) folio_put(sink); ret = netfs_wait_for_read(rreq); if (ret >= 0) { flush_dcache_folio(folio); folio_mark_uptodate(folio); } folio_unlock(folio); netfs_put_request(rreq, false, netfs_rreq_trace_put_return); return ret < 0 ? ret : 0; discard: netfs_put_request(rreq, false, netfs_rreq_trace_put_discard); alloc_error: folio_unlock(folio); return ret; } /** * netfs_read_folio - Helper to manage a read_folio request * @file: The file to read from * @folio: The folio to read * * Fulfil a read_folio request by drawing data from the cache if * possible, or the netfs if not. Space beyond the EOF is zero-filled. * Multiple I/O requests from different sources will get munged together. * * The calling netfs must initialise a netfs context contiguous to the vfs * inode before calling this. * * This is usable whether or not caching is enabled. */ int netfs_read_folio(struct file *file, struct folio *folio) { struct address_space *mapping = folio->mapping; struct netfs_io_request *rreq; struct netfs_inode *ctx = netfs_inode(mapping->host); int ret; if (folio_test_dirty(folio)) { trace_netfs_folio(folio, netfs_folio_trace_read_gaps); return netfs_read_gaps(file, folio); } _enter("%lx", folio->index); rreq = netfs_alloc_request(mapping, file, folio_pos(folio), folio_size(folio), NETFS_READPAGE); if (IS_ERR(rreq)) { ret = PTR_ERR(rreq); goto alloc_error; } ret = netfs_begin_cache_read(rreq, ctx); if (ret == -ENOMEM || ret == -EINTR || ret == -ERESTARTSYS) goto discard; netfs_stat(&netfs_n_rh_read_folio); trace_netfs_read(rreq, rreq->start, rreq->len, netfs_read_trace_readpage); /* Set up the output buffer */ ret = netfs_create_singular_buffer(rreq, folio, 0); if (ret < 0) goto discard; netfs_read_to_pagecache(rreq); ret = netfs_wait_for_read(rreq); netfs_put_request(rreq, false, netfs_rreq_trace_put_return); return ret < 0 ? ret : 0; discard: netfs_put_request(rreq, false, netfs_rreq_trace_put_discard); alloc_error: folio_unlock(folio); return ret; } EXPORT_SYMBOL(netfs_read_folio); /* * Prepare a folio for writing without reading first * @folio: The folio being prepared * @pos: starting position for the write * @len: length of write * @always_fill: T if the folio should always be completely filled/cleared * * In some cases, write_begin doesn't need to read at all: * - full folio write * - write that lies in a folio that is completely beyond EOF * - write that covers the folio from start to EOF or beyond it * * If any of these criteria are met, then zero out the unwritten parts * of the folio and return true. Otherwise, return false. */ static bool netfs_skip_folio_read(struct folio *folio, loff_t pos, size_t len, bool always_fill) { struct inode *inode = folio_inode(folio); loff_t i_size = i_size_read(inode); size_t offset = offset_in_folio(folio, pos); size_t plen = folio_size(folio); if (unlikely(always_fill)) { if (pos - offset + len <= i_size) return false; /* Page entirely before EOF */ folio_zero_segment(folio, 0, plen); folio_mark_uptodate(folio); return true; } /* Full folio write */ if (offset == 0 && len >= plen) return true; /* Page entirely beyond the end of the file */ if (pos - offset >= i_size) goto zero_out; /* Write that covers from the start of the folio to EOF or beyond */ if (offset == 0 && (pos + len) >= i_size) goto zero_out; return false; zero_out: folio_zero_segments(folio, 0, offset, offset + len, plen); return true; } /** * netfs_write_begin - Helper to prepare for writing [DEPRECATED] * @ctx: The netfs context * @file: The file to read from * @mapping: The mapping to read from * @pos: File position at which the write will begin * @len: The length of the write (may extend beyond the end of the folio chosen) * @_folio: Where to put the resultant folio * @_fsdata: Place for the netfs to store a cookie * * Pre-read data for a write-begin request by drawing data from the cache if * possible, or the netfs if not. Space beyond the EOF is zero-filled. * Multiple I/O requests from different sources will get munged together. * * The calling netfs must provide a table of operations, only one of which, * issue_read, is mandatory. * * The check_write_begin() operation can be provided to check for and flush * conflicting writes once the folio is grabbed and locked. It is passed a * pointer to the fsdata cookie that gets returned to the VM to be passed to * write_end. It is permitted to sleep. It should return 0 if the request * should go ahead or it may return an error. It may also unlock and put the * folio, provided it sets ``*foliop`` to NULL, in which case a return of 0 * will cause the folio to be re-got and the process to be retried. * * The calling netfs must initialise a netfs context contiguous to the vfs * inode before calling this. * * This is usable whether or not caching is enabled. * * Note that this should be considered deprecated and netfs_perform_write() * used instead. */ int netfs_write_begin(struct netfs_inode *ctx, struct file *file, struct address_space *mapping, loff_t pos, unsigned int len, struct folio **_folio, void **_fsdata) { struct netfs_io_request *rreq; struct folio *folio; pgoff_t index = pos >> PAGE_SHIFT; int ret; retry: folio = __filemap_get_folio(mapping, index, FGP_WRITEBEGIN, mapping_gfp_mask(mapping)); if (IS_ERR(folio)) return PTR_ERR(folio); if (ctx->ops->check_write_begin) { /* Allow the netfs (eg. ceph) to flush conflicts. */ ret = ctx->ops->check_write_begin(file, pos, len, &folio, _fsdata); if (ret < 0) { trace_netfs_failure(NULL, NULL, ret, netfs_fail_check_write_begin); goto error; } if (!folio) goto retry; } if (folio_test_uptodate(folio)) goto have_folio; /* If the folio is beyond the EOF, we want to clear it - unless it's * within the cache granule containing the EOF, in which case we need * to preload the granule. */ if (!netfs_is_cache_enabled(ctx) && netfs_skip_folio_read(folio, pos, len, false)) { netfs_stat(&netfs_n_rh_write_zskip); goto have_folio_no_wait; } rreq = netfs_alloc_request(mapping, file, folio_pos(folio), folio_size(folio), NETFS_READ_FOR_WRITE); if (IS_ERR(rreq)) { ret = PTR_ERR(rreq); goto error; } rreq->no_unlock_folio = folio->index; __set_bit(NETFS_RREQ_NO_UNLOCK_FOLIO, &rreq->flags); ret = netfs_begin_cache_read(rreq, ctx); if (ret == -ENOMEM || ret == -EINTR || ret == -ERESTARTSYS) goto error_put; netfs_stat(&netfs_n_rh_write_begin); trace_netfs_read(rreq, pos, len, netfs_read_trace_write_begin); /* Set up the output buffer */ ret = netfs_create_singular_buffer(rreq, folio, 0); if (ret < 0) goto error_put; netfs_read_to_pagecache(rreq); ret = netfs_wait_for_read(rreq); if (ret < 0) goto error; netfs_put_request(rreq, false, netfs_rreq_trace_put_return); have_folio: ret = folio_wait_private_2_killable(folio); if (ret < 0) goto error; have_folio_no_wait: *_folio = folio; _leave(" = 0"); return 0; error_put: netfs_put_request(rreq, false, netfs_rreq_trace_put_failed); error: if (folio) { folio_unlock(folio); folio_put(folio); } _leave(" = %d", ret); return ret; } EXPORT_SYMBOL(netfs_write_begin); /* * Preload the data into a folio we're proposing to write into. */ int netfs_prefetch_for_write(struct file *file, struct folio *folio, size_t offset, size_t len) { struct netfs_io_request *rreq; struct address_space *mapping = folio->mapping; struct netfs_inode *ctx = netfs_inode(mapping->host); unsigned long long start = folio_pos(folio); size_t flen = folio_size(folio); int ret; _enter("%zx @%llx", flen, start); ret = -ENOMEM; rreq = netfs_alloc_request(mapping, file, start, flen, NETFS_READ_FOR_WRITE); if (IS_ERR(rreq)) { ret = PTR_ERR(rreq); goto error; } rreq->no_unlock_folio = folio->index; __set_bit(NETFS_RREQ_NO_UNLOCK_FOLIO, &rreq->flags); ret = netfs_begin_cache_read(rreq, ctx); if (ret == -ENOMEM || ret == -EINTR || ret == -ERESTARTSYS) goto error_put; netfs_stat(&netfs_n_rh_write_begin); trace_netfs_read(rreq, start, flen, netfs_read_trace_prefetch_for_write); /* Set up the output buffer */ ret = netfs_create_singular_buffer(rreq, folio, NETFS_ROLLBUF_PAGECACHE_MARK); if (ret < 0) goto error_put; netfs_read_to_pagecache(rreq); ret = netfs_wait_for_read(rreq); netfs_put_request(rreq, false, netfs_rreq_trace_put_return); return ret < 0 ? ret : 0; error_put: netfs_put_request(rreq, false, netfs_rreq_trace_put_discard); error: _leave(" = %d", ret); return ret; } /** * netfs_buffered_read_iter - Filesystem buffered I/O read routine * @iocb: kernel I/O control block * @iter: destination for the data read * * This is the ->read_iter() routine for all filesystems that can use the page * cache directly. * * The IOCB_NOWAIT flag in iocb->ki_flags indicates that -EAGAIN shall be * returned when no data can be read without waiting for I/O requests to * complete; it doesn't prevent readahead. * * The IOCB_NOIO flag in iocb->ki_flags indicates that no new I/O requests * shall be made for the read or for readahead. When no data can be read, * -EAGAIN shall be returned. When readahead would be triggered, a partial, * possibly empty read shall be returned. * * Return: * * number of bytes copied, even for partial reads * * negative error code (or 0 if IOCB_NOIO) if nothing was read */ ssize_t netfs_buffered_read_iter(struct kiocb *iocb, struct iov_iter *iter) { struct inode *inode = file_inode(iocb->ki_filp); struct netfs_inode *ictx = netfs_inode(inode); ssize_t ret; if (WARN_ON_ONCE((iocb->ki_flags & IOCB_DIRECT) || test_bit(NETFS_ICTX_UNBUFFERED, &ictx->flags))) return -EINVAL; ret = netfs_start_io_read(inode); if (ret == 0) { ret = filemap_read(iocb, iter, 0); netfs_end_io_read(inode); } return ret; } EXPORT_SYMBOL(netfs_buffered_read_iter); /** * netfs_file_read_iter - Generic filesystem read routine * @iocb: kernel I/O control block * @iter: destination for the data read * * This is the ->read_iter() routine for all filesystems that can use the page * cache directly. * * The IOCB_NOWAIT flag in iocb->ki_flags indicates that -EAGAIN shall be * returned when no data can be read without waiting for I/O requests to * complete; it doesn't prevent readahead. * * The IOCB_NOIO flag in iocb->ki_flags indicates that no new I/O requests * shall be made for the read or for readahead. When no data can be read, * -EAGAIN shall be returned. When readahead would be triggered, a partial, * possibly empty read shall be returned. * * Return: * * number of bytes copied, even for partial reads * * negative error code (or 0 if IOCB_NOIO) if nothing was read */ ssize_t netfs_file_read_iter(struct kiocb *iocb, struct iov_iter *iter) { struct netfs_inode *ictx = netfs_inode(iocb->ki_filp->f_mapping->host); if ((iocb->ki_flags & IOCB_DIRECT) || test_bit(NETFS_ICTX_UNBUFFERED, &ictx->flags)) return netfs_unbuffered_read_iter(iocb, iter); return netfs_buffered_read_iter(iocb, iter); } EXPORT_SYMBOL(netfs_file_read_iter);