diff --git a/tests/sys/fs/fusefs/bmap.cc b/tests/sys/fs/fusefs/bmap.cc index 56821f367a82..91d8ab563690 100644 --- a/tests/sys/fs/fusefs/bmap.cc +++ b/tests/sys/fs/fusefs/bmap.cc @@ -1,256 +1,258 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2019 The FreeBSD Foundation * * This software was developed by BFF Storage Systems, LLC under sponsorship * from the FreeBSD Foundation. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD$ */ extern "C" { #include #include #include #include } #include "mockfs.hh" #include "utils.hh" using namespace testing; const static char FULLPATH[] = "mountpoint/foo"; const static char RELPATH[] = "foo"; class Bmap: public FuseTest { public: virtual void SetUp() { m_maxreadahead = UINT32_MAX; FuseTest::SetUp(); } void expect_bmap(uint64_t ino, uint64_t lbn, uint32_t blocksize, uint64_t pbn) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_BMAP && in.header.nodeid == ino && in.body.bmap.block == lbn && in.body.bmap.blocksize == blocksize); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto i __unused, auto& out) { SET_OUT_HEADER_LEN(out, bmap); out.body.bmap.block = pbn; }))); } void expect_lookup(const char *relpath, uint64_t ino, off_t size) { FuseTest::expect_lookup(relpath, ino, S_IFREG | 0644, size, 1, UINT64_MAX); } }; class BmapEof: public Bmap, public WithParamInterface {}; /* * Test FUSE_BMAP * XXX The FUSE protocol does not include the runp and runb variables, so those * must be guessed in-kernel. */ TEST_F(Bmap, bmap) { struct fiobmap2_arg arg; /* * Pick fsize and lbn large enough that max length runs won't reach * either beginning or end of file */ const off_t filesize = 1 << 30; int64_t lbn = 100; int64_t pbn = 12345; const ino_t ino = 42; int fd; expect_lookup(RELPATH, 42, filesize); expect_open(ino, 0, 1); expect_bmap(ino, lbn, m_maxbcachebuf, pbn); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); arg.bn = lbn; arg.runp = -1; arg.runb = -1; ASSERT_EQ(0, ioctl(fd, FIOBMAP2, &arg)) << strerror(errno); EXPECT_EQ(arg.bn, pbn); EXPECT_EQ(arg.runp, m_maxphys / m_maxbcachebuf - 1); EXPECT_EQ(arg.runb, m_maxphys / m_maxbcachebuf - 1); leak(fd); } /* * If the daemon does not implement VOP_BMAP, fusefs should return sensible * defaults. */ TEST_F(Bmap, default_) { struct fiobmap2_arg arg; const off_t filesize = 1 << 30; const ino_t ino = 42; int64_t lbn; int fd; expect_lookup(RELPATH, 42, filesize); expect_open(ino, 0, 1); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_BMAP); }, Eq(true)), _) ).WillOnce(Invoke(ReturnErrno(ENOSYS))); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); /* First block */ lbn = 0; arg.bn = lbn; arg.runp = -1; arg.runb = -1; ASSERT_EQ(0, ioctl(fd, FIOBMAP2, &arg)) << strerror(errno); EXPECT_EQ(arg.bn, 0); EXPECT_EQ(arg.runp, m_maxphys / m_maxbcachebuf - 1); EXPECT_EQ(arg.runb, 0); /* In the middle */ lbn = filesize / m_maxbcachebuf / 2; arg.bn = lbn; arg.runp = -1; arg.runb = -1; ASSERT_EQ(0, ioctl(fd, FIOBMAP2, &arg)) << strerror(errno); EXPECT_EQ(arg.bn, lbn * m_maxbcachebuf / DEV_BSIZE); EXPECT_EQ(arg.runp, m_maxphys / m_maxbcachebuf - 1); EXPECT_EQ(arg.runb, m_maxphys / m_maxbcachebuf - 1); /* Last block */ lbn = filesize / m_maxbcachebuf - 1; arg.bn = lbn; arg.runp = -1; arg.runb = -1; ASSERT_EQ(0, ioctl(fd, FIOBMAP2, &arg)) << strerror(errno); EXPECT_EQ(arg.bn, lbn * m_maxbcachebuf / DEV_BSIZE); EXPECT_EQ(arg.runp, 0); EXPECT_EQ(arg.runb, m_maxphys / m_maxbcachebuf - 1); leak(fd); } /* * VOP_BMAP should not query the server for the file's size, even if its cached * attributes have expired. * Regression test for https://bugs.freebsd.org/bugzilla/show_bug.cgi?id=256937 */ TEST_P(BmapEof, eof) { /* * Outline: * 1) lookup the file, setting attr_valid=0 * 2) Read more than one block, causing the kernel to issue VOP_BMAP to * plan readahead. * 3) Nothing should panic * 4) Repeat the tests, truncating the file after different numbers of * GETATTR operations. */ Sequence seq; const off_t filesize = 2 * m_maxbcachebuf; const ino_t ino = 42; mode_t mode = S_IFREG | 0644; void *buf; int fd; int ngetattrs; ngetattrs = GetParam(); FuseTest::expect_lookup(RELPATH, ino, mode, filesize, 1, 0); expect_open(ino, 0, 1); // Depending on ngetattrs, FUSE_READ could be called with either // filesize or filesize / 2 . EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_READ && in.header.nodeid == ino && in.body.read.offset == 0 && ( in.body.read.size == filesize || in.body.read.size == filesize / 2)); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in, auto& out) { size_t osize = in.body.read.size; + + assert(osize < sizeof(out.body.bytes)); out.header.len = sizeof(struct fuse_out_header) + osize; bzero(out.body.bytes, osize); }))); EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { return (in.header.opcode == FUSE_GETATTR && in.header.nodeid == ino); }, Eq(true)), _) ).Times(Between(ngetattrs - 1, ngetattrs)) .InSequence(seq) .WillRepeatedly(Invoke(ReturnImmediate([=](auto i __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr_valid = 0; out.body.attr.attr.ino = ino; out.body.attr.attr.mode = S_IFREG | 0644; out.body.attr.attr.size = filesize; }))); EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { return (in.header.opcode == FUSE_GETATTR && in.header.nodeid == ino); }, Eq(true)), _) ).InSequence(seq) .WillRepeatedly(Invoke(ReturnImmediate([=](auto i __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr_valid = 0; out.body.attr.attr.ino = ino; out.body.attr.attr.mode = S_IFREG | 0644; out.body.attr.attr.size = filesize / 2; }))); buf = calloc(1, filesize); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); read(fd, buf, filesize); leak(fd); } INSTANTIATE_TEST_CASE_P(BE, BmapEof, Values(1, 2, 3) ); diff --git a/tests/sys/fs/fusefs/io.cc b/tests/sys/fs/fusefs/io.cc index 1502bd263f51..a8815434c6d8 100644 --- a/tests/sys/fs/fusefs/io.cc +++ b/tests/sys/fs/fusefs/io.cc @@ -1,521 +1,524 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2019 The FreeBSD Foundation * * This software was developed by BFF Storage Systems, LLC under sponsorship * from the FreeBSD Foundation. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD$ */ extern "C" { #include #include #include #include #include #include } #include "mockfs.hh" #include "utils.hh" /* * For testing I/O like fsx does, but deterministically and without a real * underlying file system */ using namespace testing; const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const uint64_t ino = 42; static void compare(const void *tbuf, const void *controlbuf, off_t baseofs, ssize_t size) { int i; for (i = 0; i < size; i++) { if (((const char*)tbuf)[i] != ((const char*)controlbuf)[i]) { off_t ofs = baseofs + i; FAIL() << "miscompare at offset " << std::hex << std::showbase << ofs << ". expected = " << std::setw(2) << (unsigned)((const uint8_t*)controlbuf)[i] << " got = " << (unsigned)((const uint8_t*)tbuf)[i]; } } } typedef tuple IoParam; class Io: public FuseTest, public WithParamInterface { public: int m_backing_fd, m_control_fd, m_test_fd; off_t m_filesize; bool m_direct_io; Io(): m_backing_fd(-1), m_control_fd(-1), m_test_fd(-1), m_filesize(0), m_direct_io(false) {}; void SetUp() { m_backing_fd = open("backing_file", O_RDWR | O_CREAT | O_TRUNC, 0644); if (m_backing_fd < 0) FAIL() << strerror(errno); m_control_fd = open("control", O_RDWR | O_CREAT | O_TRUNC, 0644); if (m_control_fd < 0) FAIL() << strerror(errno); srandom(22'9'1982); // Seed with my birthday if (get<0>(GetParam())) m_init_flags |= FUSE_ASYNC_READ; m_maxwrite = get<1>(GetParam()); switch (get<2>(GetParam())) { case Uncached: m_direct_io = true; break; case WritebackAsync: m_async = true; /* FALLTHROUGH */ case Writeback: m_init_flags |= FUSE_WRITEBACK_CACHE; /* FALLTHROUGH */ case Writethrough: break; default: FAIL() << "Unknown cache mode"; } m_noatime = true; // To prevent SETATTR for atime on close FuseTest::SetUp(); if (IsSkipped()) return; if (verbosity > 0) { printf("Test Parameters: init_flags=%#x maxwrite=%#x " "%sasync cache=%s\n", m_init_flags, m_maxwrite, m_async? "" : "no", cache_mode_to_s(get<2>(GetParam()))); } expect_lookup(RELPATH, ino, S_IFREG | 0644, 0, 1); expect_open(ino, m_direct_io ? FOPEN_DIRECT_IO : 0, 1); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_WRITE && in.header.nodeid == ino); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnImmediate([=](auto in, auto& out) { const char *buf = (const char*)in.body.bytes + sizeof(struct fuse_write_in); ssize_t isize = in.body.write.size; off_t iofs = in.body.write.offset; + assert((size_t)isize <= sizeof(in.body.bytes) - + sizeof(struct fuse_write_in)); ASSERT_EQ(isize, pwrite(m_backing_fd, buf, isize, iofs)) << strerror(errno); SET_OUT_HEADER_LEN(out, write); out.body.write.size = isize; }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_READ && in.header.nodeid == ino); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnImmediate([=](auto in, auto& out) { ssize_t isize = in.body.write.size; off_t iofs = in.body.write.offset; void *buf = out.body.bytes; ssize_t osize; + assert((size_t)isize <= sizeof(out.body.bytes)); osize = pread(m_backing_fd, buf, isize, iofs); ASSERT_LE(0, osize) << strerror(errno); out.header.len = sizeof(struct fuse_out_header) + osize; }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && (in.body.setattr.valid & FATTR_SIZE)); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnImmediate([=](auto in, auto& out) { ASSERT_EQ(0, ftruncate(m_backing_fd, in.body.setattr.size)) << strerror(errno); SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; out.body.attr.attr.mode = S_IFREG | 0755; out.body.attr.attr.size = in.body.setattr.size; out.body.attr.attr_valid = UINT64_MAX; }))); /* Any test that close()s will send FUSE_FLUSH and FUSE_RELEASE */ EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_FLUSH && in.header.nodeid == ino); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnErrno(0))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_RELEASE && in.header.nodeid == ino); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnErrno(0))); m_test_fd = open(FULLPATH, O_RDWR ); EXPECT_LE(0, m_test_fd) << strerror(errno); } void TearDown() { if (m_test_fd >= 0) close(m_test_fd); if (m_backing_fd >= 0) close(m_backing_fd); if (m_control_fd >= 0) close(m_control_fd); FuseTest::TearDown(); leak(m_test_fd); } void do_closeopen() { ASSERT_EQ(0, close(m_test_fd)) << strerror(errno); m_test_fd = open("backing_file", O_RDWR); ASSERT_LE(0, m_test_fd) << strerror(errno); ASSERT_EQ(0, close(m_control_fd)) << strerror(errno); m_control_fd = open("control", O_RDWR); ASSERT_LE(0, m_control_fd) << strerror(errno); } void do_ftruncate(off_t offs) { ASSERT_EQ(0, ftruncate(m_test_fd, offs)) << strerror(errno); ASSERT_EQ(0, ftruncate(m_control_fd, offs)) << strerror(errno); m_filesize = offs; } void do_mapread(ssize_t size, off_t offs) { void *control_buf, *p; off_t pg_offset, page_mask; size_t map_size; page_mask = getpagesize() - 1; pg_offset = offs & page_mask; map_size = pg_offset + size; p = mmap(NULL, map_size, PROT_READ, MAP_FILE | MAP_SHARED, m_test_fd, offs - pg_offset); ASSERT_NE(p, MAP_FAILED) << strerror(errno); control_buf = malloc(size); ASSERT_NE(nullptr, control_buf) << strerror(errno); ASSERT_EQ(size, pread(m_control_fd, control_buf, size, offs)) << strerror(errno); compare((void*)((char*)p + pg_offset), control_buf, offs, size); ASSERT_EQ(0, munmap(p, map_size)) << strerror(errno); free(control_buf); } void do_read(ssize_t size, off_t offs) { void *test_buf, *control_buf; ssize_t r; test_buf = malloc(size); ASSERT_NE(nullptr, test_buf) << strerror(errno); control_buf = malloc(size); ASSERT_NE(nullptr, control_buf) << strerror(errno); errno = 0; r = pread(m_test_fd, test_buf, size, offs); ASSERT_NE(-1, r) << strerror(errno); ASSERT_EQ(size, r) << "unexpected short read"; r = pread(m_control_fd, control_buf, size, offs); ASSERT_NE(-1, r) << strerror(errno); ASSERT_EQ(size, r) << "unexpected short read"; compare(test_buf, control_buf, offs, size); free(control_buf); free(test_buf); } void do_mapwrite(ssize_t size, off_t offs) { char *buf; void *p; off_t pg_offset, page_mask; size_t map_size; long i; page_mask = getpagesize() - 1; pg_offset = offs & page_mask; map_size = pg_offset + size; buf = (char*)malloc(size); ASSERT_NE(nullptr, buf) << strerror(errno); for (i=0; i < size; i++) buf[i] = random(); if (offs + size > m_filesize) { /* * Must manually extend. vm_mmap_vnode will not implicitly * extend a vnode */ do_ftruncate(offs + size); } p = mmap(NULL, map_size, PROT_READ | PROT_WRITE, MAP_FILE | MAP_SHARED, m_test_fd, offs - pg_offset); ASSERT_NE(p, MAP_FAILED) << strerror(errno); bcopy(buf, (char*)p + pg_offset, size); ASSERT_EQ(size, pwrite(m_control_fd, buf, size, offs)) << strerror(errno); free(buf); ASSERT_EQ(0, munmap(p, map_size)) << strerror(errno); } void do_write(ssize_t size, off_t offs) { char *buf; long i; buf = (char*)malloc(size); ASSERT_NE(nullptr, buf) << strerror(errno); for (i=0; i < size; i++) buf[i] = random(); ASSERT_EQ(size, pwrite(m_test_fd, buf, size, offs )) << strerror(errno); ASSERT_EQ(size, pwrite(m_control_fd, buf, size, offs)) << strerror(errno); m_filesize = std::max(m_filesize, offs + size); free(buf); } }; class IoCacheable: public Io { public: virtual void SetUp() { Io::SetUp(); } }; /* * Extend a file with dirty data in the last page of the last block. * * fsx -WR -P /tmp -S8 -N3 fsx.bin */ TEST_P(Io, extend_from_dirty_page) { off_t wofs = 0x21a0; ssize_t wsize = 0xf0a8; off_t rofs = 0xb284; ssize_t rsize = 0x9b22; off_t truncsize = 0x28702; do_write(wsize, wofs); do_ftruncate(truncsize); do_read(rsize, rofs); } /* * mapwrite into a newly extended part of a file. * * fsx -c 100 -i 100 -l 524288 -o 131072 -N5 -P /tmp -S19 fsx.bin */ TEST_P(IoCacheable, extend_by_mapwrite) { do_mapwrite(0x849e, 0x29a3a); /* [0x29a3a, 0x31ed7] */ do_mapwrite(0x3994, 0x3c7d8); /* [0x3c7d8, 0x4016b] */ do_read(0xf556, 0x30c16); /* [0x30c16, 0x4016b] */ } /* * When writing the last page of a file, it must be written synchronously. * Otherwise the cached page can become invalid by a subsequent extend * operation. * * fsx -WR -P /tmp -S642 -N3 fsx.bin */ TEST_P(Io, last_page) { do_write(0xcc77, 0x1134f); /* [0x1134f, 0x1dfc5] */ do_write(0xdfa7, 0x2096a); /* [0x2096a, 0x2e910] */ do_read(0xb5b7, 0x1a3aa); /* [0x1a3aa, 0x25960] */ } /* * Read a hole using mmap * * fsx -c 100 -i 100 -l 524288 -o 131072 -N11 -P /tmp -S14 fsx.bin */ TEST_P(IoCacheable, mapread_hole) { do_write(0x123b7, 0xf205); /* [0xf205, 0x215bb] */ do_mapread(0xeeea, 0x2f4c); /* [0x2f4c, 0x11e35] */ } /* * Read a hole from a block that contains some cached data. * * fsx -WR -P /tmp -S55 fsx.bin */ TEST_P(Io, read_hole_from_cached_block) { off_t wofs = 0x160c5; ssize_t wsize = 0xa996; off_t rofs = 0x472e; ssize_t rsize = 0xd8d5; do_write(wsize, wofs); do_read(rsize, rofs); } /* * Truncating a file into a dirty buffer should not causing anything untoward * to happen when that buffer is eventually flushed. * * fsx -WR -P /tmp -S839 -d -N6 fsx.bin */ TEST_P(Io, truncate_into_dirty_buffer) { off_t wofs0 = 0x3bad7; ssize_t wsize0 = 0x4529; off_t wofs1 = 0xc30d; ssize_t wsize1 = 0x5f77; off_t truncsize0 = 0x10916; off_t rofs = 0xdf17; ssize_t rsize = 0x29ff; off_t truncsize1 = 0x152b4; do_write(wsize0, wofs0); do_write(wsize1, wofs1); do_ftruncate(truncsize0); do_read(rsize, rofs); do_ftruncate(truncsize1); close(m_test_fd); } /* * Truncating a file into a dirty buffer should not causing anything untoward * to happen when that buffer is eventually flushed, even when the buffer's * dirty_off is > 0. * * Based on this command with a few steps removed: * fsx -WR -P /tmp -S677 -d -N8 fsx.bin */ TEST_P(Io, truncate_into_dirty_buffer2) { off_t truncsize0 = 0x344f3; off_t wofs = 0x2790c; ssize_t wsize = 0xd86a; off_t truncsize1 = 0x2de38; off_t rofs2 = 0x1fd7a; ssize_t rsize2 = 0xc594; off_t truncsize2 = 0x31e71; /* Sets the file size to something larger than the next write */ do_ftruncate(truncsize0); /* * Creates a dirty buffer. The part in lbn 2 doesn't flush * synchronously. */ do_write(wsize, wofs); /* Truncates part of the dirty buffer created in step 2 */ do_ftruncate(truncsize1); /* XXX ?I don't know why this is necessary? */ do_read(rsize2, rofs2); /* Truncates the dirty buffer */ do_ftruncate(truncsize2); close(m_test_fd); } /* * Regression test for a bug introduced in r348931 * * Sequence of operations: * 1) The first write reads lbn so it can modify it * 2) The first write flushes lbn 3 immediately because it's the end of file * 3) The first write then flushes lbn 4 because it's the end of the file * 4) The second write modifies the cached versions of lbn 3 and 4 * 5) The third write's getblkx invalidates lbn 4's B_CACHE because it's * extending the buffer. Then it flushes lbn 4 because B_DELWRI was set but * B_CACHE was clear. * 6) fuse_write_biobackend erroneously called vfs_bio_clrbuf, putting the * buffer into a weird write-only state. All read operations would return * 0. Writes were apparently still processed, because the buffer's contents * were correct when examined in a core dump. * 7) The third write reads lbn 4 because cache is clear * 9) uiomove dutifully copies new data into the buffer * 10) The buffer's dirty is flushed to lbn 4 * 11) The read returns all zeros because of step 6. * * Based on: * fsx -WR -l 524388 -o 131072 -P /tmp -S6456 -q fsx.bin */ TEST_P(Io, resize_a_valid_buffer_while_extending) { do_write(0x14530, 0x36ee6); /* [0x36ee6, 0x4b415] */ do_write(0x1507c, 0x33256); /* [0x33256, 0x482d1] */ do_write(0x175c, 0x4c03d); /* [0x4c03d, 0x4d798] */ do_read(0xe277, 0x3599c); /* [0x3599c, 0x43c12] */ close(m_test_fd); } INSTANTIATE_TEST_CASE_P(Io, Io, Combine(Bool(), /* async read */ Values(0x1000, 0x10000, 0x20000), /* m_maxwrite */ Values(Uncached, Writethrough, Writeback, WritebackAsync) ) ); INSTANTIATE_TEST_CASE_P(Io, IoCacheable, Combine(Bool(), /* async read */ Values(0x1000, 0x10000, 0x20000), /* m_maxwrite */ Values(Writethrough, Writeback, WritebackAsync) ) ); diff --git a/tests/sys/fs/fusefs/mockfs.hh b/tests/sys/fs/fusefs/mockfs.hh index 121d985e56fe..edbaf7ef770f 100644 --- a/tests/sys/fs/fusefs/mockfs.hh +++ b/tests/sys/fs/fusefs/mockfs.hh @@ -1,432 +1,432 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2019 The FreeBSD Foundation * * This software was developed by BFF Storage Systems, LLC under sponsorship * from the FreeBSD Foundation. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD$ */ extern "C" { #include #include #include "fuse_kernel.h" } #include #define TIME_T_MAX (std::numeric_limits::max()) /* * A pseudo-fuse errno used indicate that a fuse operation should have no * response, at least not immediately */ #define FUSE_NORESPONSE 9999 #define SET_OUT_HEADER_LEN(out, variant) { \ (out).header.len = (sizeof((out).header) + \ sizeof((out).body.variant)); \ } /* * Create an expectation on FUSE_LOOKUP and return it so the caller can set * actions. * * This must be a macro instead of a method because EXPECT_CALL returns a type * with a deleted constructor. */ #define EXPECT_LOOKUP(parent, path) \ EXPECT_CALL(*m_mock, process( \ ResultOf([=](auto in) { \ return (in.header.opcode == FUSE_LOOKUP && \ in.header.nodeid == (parent) && \ strcmp(in.body.lookup, (path)) == 0); \ }, Eq(true)), \ _) \ ) extern int verbosity; /* * The maximum that a test case can set max_write, limited by the buffer * supplied when reading from /dev/fuse. This limitation is imposed by * fusefs-libs, but not by the FUSE protocol. */ const uint32_t max_max_write = 0x20000; /* This struct isn't defined by fuse_kernel.h or libfuse, but it should be */ struct fuse_create_out { struct fuse_entry_out entry; struct fuse_open_out open; }; /* Protocol 7.8 version of struct fuse_attr */ struct fuse_attr_7_8 { uint64_t ino; uint64_t size; uint64_t blocks; uint64_t atime; uint64_t mtime; uint64_t ctime; uint32_t atimensec; uint32_t mtimensec; uint32_t ctimensec; uint32_t mode; uint32_t nlink; uint32_t uid; uint32_t gid; uint32_t rdev; }; /* Protocol 7.8 version of struct fuse_attr_out */ struct fuse_attr_out_7_8 { uint64_t attr_valid; uint32_t attr_valid_nsec; uint32_t dummy; struct fuse_attr_7_8 attr; }; /* Protocol 7.8 version of struct fuse_entry_out */ struct fuse_entry_out_7_8 { uint64_t nodeid; /* Inode ID */ uint64_t generation; /* Inode generation: nodeid:gen must be unique for the fs's lifetime */ uint64_t entry_valid; /* Cache timeout for the name */ uint64_t attr_valid; /* Cache timeout for the attributes */ uint32_t entry_valid_nsec; uint32_t attr_valid_nsec; struct fuse_attr_7_8 attr; }; /* Output struct for FUSE_CREATE for protocol 7.8 servers */ struct fuse_create_out_7_8 { struct fuse_entry_out_7_8 entry; struct fuse_open_out open; }; /* Output struct for FUSE_INIT for protocol 7.22 and earlier servers */ struct fuse_init_out_7_22 { uint32_t major; uint32_t minor; uint32_t max_readahead; uint32_t flags; uint16_t max_background; uint16_t congestion_threshold; uint32_t max_write; }; union fuse_payloads_in { fuse_access_in access; fuse_bmap_in bmap; /* * In fusefs-libs 3.4.2 and below the buffer size is fixed at 0x21000 * minus the header sizes. fusefs-libs 3.4.3 (and FUSE Protocol 7.29) * add a FUSE_MAX_PAGES option that allows it to be greater. * * See fuse_kern_chan.c in fusefs-libs 2.9.9 and below, or * FUSE_DEFAULT_MAX_PAGES_PER_REQ in fusefs-libs 3.4.3 and above. */ uint8_t bytes[ max_max_write + 0x1000 - sizeof(struct fuse_in_header) ]; fuse_copy_file_range_in copy_file_range; fuse_create_in create; fuse_fallocate_in fallocate; fuse_flush_in flush; fuse_fsync_in fsync; fuse_fsync_in fsyncdir; fuse_forget_in forget; fuse_getattr_in getattr; fuse_interrupt_in interrupt; fuse_lk_in getlk; fuse_getxattr_in getxattr; fuse_init_in init; fuse_link_in link; fuse_listxattr_in listxattr; char lookup[0]; fuse_lseek_in lseek; fuse_mkdir_in mkdir; fuse_mknod_in mknod; fuse_open_in open; fuse_open_in opendir; fuse_read_in read; fuse_read_in readdir; fuse_release_in release; fuse_release_in releasedir; fuse_rename_in rename; char rmdir[0]; fuse_setattr_in setattr; fuse_setxattr_in setxattr; fuse_lk_in setlk; fuse_lk_in setlkw; char unlink[0]; fuse_write_in write; }; struct mockfs_buf_in { fuse_in_header header; union fuse_payloads_in body; }; union fuse_payloads_out { fuse_attr_out attr; fuse_attr_out_7_8 attr_7_8; fuse_bmap_out bmap; fuse_create_out create; fuse_create_out_7_8 create_7_8; /* * The protocol places no limits on the size of bytes. Choose * a size big enough for anything we'll test. */ - uint8_t bytes[0x20000]; + uint8_t bytes[0x40000]; fuse_entry_out entry; fuse_entry_out_7_8 entry_7_8; fuse_lk_out getlk; fuse_getxattr_out getxattr; fuse_init_out init; fuse_init_out_7_22 init_7_22; fuse_lseek_out lseek; /* The inval_entry structure should be followed by the entry's name */ fuse_notify_inval_entry_out inval_entry; fuse_notify_inval_inode_out inval_inode; /* The store structure should be followed by the data to store */ fuse_notify_store_out store; fuse_listxattr_out listxattr; fuse_open_out open; fuse_statfs_out statfs; /* * The protocol places no limits on the length of the string. This is * merely convenient for testing. */ char str[80]; fuse_write_out write; }; struct mockfs_buf_out { fuse_out_header header; union fuse_payloads_out body; /* Default constructor: zero everything */ mockfs_buf_out() { memset(this, 0, sizeof(*this)); } }; /* A function that can be invoked in place of MockFS::process */ typedef std::function> &out)> ProcessMockerT; /* * Helper function used for setting an error expectation for any fuse operation. * The operation will return the supplied error */ ProcessMockerT ReturnErrno(int error); /* Helper function used for returning negative cache entries for LOOKUP */ ProcessMockerT ReturnNegativeCache(const struct timespec *entry_valid); /* Helper function used for returning a single immediate response */ ProcessMockerT ReturnImmediate( std::function f); /* How the daemon should check /dev/fuse for readiness */ enum poll_method { BLOCKING, SELECT, POLL, KQ }; /* * Fake FUSE filesystem * * "Mounts" a filesystem to a temporary directory and services requests * according to the programmed expectations. * * Operates directly on the fusefs(4) kernel API, not the libfuse(3) user api. */ class MockFS { /* * thread id of the fuse daemon thread * * It must run in a separate thread so it doesn't deadlock with the * client test code. */ pthread_t m_daemon_id; /* file descriptor of /dev/fuse control device */ volatile int m_fuse_fd; /* The minor version of the kernel API that this mock daemon targets */ uint32_t m_kernel_minor_version; int m_kq; /* The max_readahead file system option */ uint32_t m_maxreadahead; /* pid of the test process */ pid_t m_pid; /* The unique value of the header of the last received operation */ uint64_t m_last_unique; /* Method the daemon should use for I/O to and from /dev/fuse */ enum poll_method m_pm; /* Timestamp granularity in nanoseconds */ unsigned m_time_gran; void audit_request(const mockfs_buf_in &in, ssize_t buflen); void debug_request(const mockfs_buf_in&, ssize_t buflen); void debug_response(const mockfs_buf_out&); /* Initialize a session after mounting */ void init(uint32_t flags); /* Is pid from a process that might be involved in the test? */ bool pid_ok(pid_t pid); /* Default request handler */ void process_default(const mockfs_buf_in&, std::vector>&); /* Entry point for the daemon thread */ static void* service(void*); /* * Read, but do not process, a single request from the kernel * * @param in Return storage for the FUSE request * @param res Return value of read(2). If positive, the amount of * data read from the fuse device. */ void read_request(mockfs_buf_in& in, ssize_t& res); /* Write a single response back to the kernel */ void write_response(const mockfs_buf_out &out); public: /* pid of child process, for two-process test cases */ pid_t m_child_pid; /* the expected errno of the next write to /dev/fuse */ int m_expected_write_errno; /* Maximum size of a FUSE_WRITE write */ uint32_t m_maxwrite; /* * Number of events that were available from /dev/fuse after the last * kevent call. Only valid when m_pm = KQ. */ int m_nready; /* Tell the daemon to shut down ASAP */ bool m_quit; /* Create a new mockfs and mount it to a tempdir */ MockFS(int max_readahead, bool allow_other, bool default_permissions, bool push_symlinks_in, bool ro, enum poll_method pm, uint32_t flags, uint32_t kernel_minor_version, uint32_t max_write, bool async, bool no_clusterr, unsigned time_gran, bool nointr, bool noatime, const char *fsname, const char *subtype); virtual ~MockFS(); /* Kill the filesystem daemon without unmounting the filesystem */ void kill_daemon(); /* Process FUSE requests endlessly */ void loop(); /* * Send an asynchronous notification to invalidate a directory entry. * Similar to libfuse's fuse_lowlevel_notify_inval_entry * * This method will block until the client has responded, so it should * generally be run in a separate thread from request processing. * * @param parent Parent directory's inode number * @param name name of dirent to invalidate * @param namelen size of name, including the NUL */ int notify_inval_entry(ino_t parent, const char *name, size_t namelen); /* * Send an asynchronous notification to invalidate an inode's cached * data and/or attributes. Similar to libfuse's * fuse_lowlevel_notify_inval_inode. * * This method will block until the client has responded, so it should * generally be run in a separate thread from request processing. * * @param ino File's inode number * @param off offset at which to begin invalidation. A * negative offset means to invalidate attributes * only. * @param len Size of region of data to invalidate. 0 means * to invalidate all cached data. */ int notify_inval_inode(ino_t ino, off_t off, ssize_t len); /* * Send an asynchronous notification to store data directly into an * inode's cache. Similar to libfuse's fuse_lowlevel_notify_store. * * This method will block until the client has responded, so it should * generally be run in a separate thread from request processing. * * @param ino File's inode number * @param off Offset at which to store data * @param data Pointer to the data to cache * @param len Size of data */ int notify_store(ino_t ino, off_t off, const void* data, ssize_t size); /* * Request handler * * This method is expected to provide the responses to each FUSE * operation. For an immediate response, push one buffer into out. * For a delayed response, push nothing. For an immediate response * plus a delayed response to an earlier operation, push two bufs. * Test cases must define each response using Googlemock expectations */ MOCK_METHOD2(process, void(const mockfs_buf_in&, std::vector>&)); /* Gracefully unmount */ void unmount(); }; diff --git a/tests/sys/fs/fusefs/setattr.cc b/tests/sys/fs/fusefs/setattr.cc index e245c274ba07..e08f2124e06f 100644 --- a/tests/sys/fs/fusefs/setattr.cc +++ b/tests/sys/fs/fusefs/setattr.cc @@ -1,868 +1,869 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2019 The FreeBSD Foundation * * This software was developed by BFF Storage Systems, LLC under sponsorship * from the FreeBSD Foundation. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD$ */ extern "C" { #include #include #include #include #include #include #include } #include "mockfs.hh" #include "utils.hh" using namespace testing; class Setattr : public FuseTest { public: static sig_atomic_t s_sigxfsz; }; class RofsSetattr: public Setattr { public: virtual void SetUp() { s_sigxfsz = 0; m_ro = true; Setattr::SetUp(); } }; class Setattr_7_8: public Setattr { public: virtual void SetUp() { m_kernel_minor_version = 8; Setattr::SetUp(); } }; sig_atomic_t Setattr::s_sigxfsz = 0; void sigxfsz_handler(int __unused sig) { Setattr::s_sigxfsz = 1; } /* * If setattr returns a non-zero cache timeout, then subsequent VOP_GETATTRs * should use the cached attributes, rather than query the daemon */ TEST_F(Setattr, attr_cache) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const uint64_t ino = 42; struct stat sb; const mode_t newmode = 0644; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillRepeatedly(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | 0644; out.body.entry.nodeid = ino; out.body.entry.entry_valid = UINT64_MAX; }))); EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; // Must match nodeid out.body.attr.attr.mode = S_IFREG | newmode; out.body.attr.attr_valid = UINT64_MAX; }))); EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { return (in.header.opcode == FUSE_GETATTR); }, Eq(true)), _) ).Times(0); /* Set an attribute with SETATTR */ ASSERT_EQ(0, chmod(FULLPATH, newmode)) << strerror(errno); /* The stat(2) should use cached attributes */ ASSERT_EQ(0, stat(FULLPATH, &sb)); EXPECT_EQ(S_IFREG | newmode, sb.st_mode); } /* Change the mode of a file */ TEST_F(Setattr, chmod) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const uint64_t ino = 42; const mode_t oldmode = 0755; const mode_t newmode = 0644; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | oldmode; out.body.entry.nodeid = ino; }))); EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { uint32_t valid = FATTR_MODE; return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && in.body.setattr.valid == valid && in.body.setattr.mode == newmode); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; // Must match nodeid out.body.attr.attr.mode = S_IFREG | newmode; }))); EXPECT_EQ(0, chmod(FULLPATH, newmode)) << strerror(errno); } /* * Chmod a multiply-linked file with cached attributes. Check that both files' * attributes have changed. */ TEST_F(Setattr, chmod_multiply_linked) { const char FULLPATH0[] = "mountpoint/some_file.txt"; const char RELPATH0[] = "some_file.txt"; const char FULLPATH1[] = "mountpoint/other_file.txt"; const char RELPATH1[] = "other_file.txt"; struct stat sb; const uint64_t ino = 42; const mode_t oldmode = 0777; const mode_t newmode = 0666; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH0) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | oldmode; out.body.entry.nodeid = ino; out.body.entry.attr.nlink = 2; out.body.entry.attr_valid = UINT64_MAX; out.body.entry.entry_valid = UINT64_MAX; }))); EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH1) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | oldmode; out.body.entry.nodeid = ino; out.body.entry.attr.nlink = 2; out.body.entry.attr_valid = UINT64_MAX; out.body.entry.entry_valid = UINT64_MAX; }))); EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { uint32_t valid = FATTR_MODE; return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && in.body.setattr.valid == valid && in.body.setattr.mode == newmode); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; out.body.attr.attr.mode = S_IFREG | newmode; out.body.attr.attr.nlink = 2; out.body.attr.attr_valid = UINT64_MAX; }))); /* For a lookup of the 2nd file to get it into the cache*/ ASSERT_EQ(0, stat(FULLPATH1, &sb)) << strerror(errno); EXPECT_EQ(S_IFREG | oldmode, sb.st_mode); ASSERT_EQ(0, chmod(FULLPATH0, newmode)) << strerror(errno); ASSERT_EQ(0, stat(FULLPATH0, &sb)) << strerror(errno); EXPECT_EQ(S_IFREG | newmode, sb.st_mode); ASSERT_EQ(0, stat(FULLPATH1, &sb)) << strerror(errno); EXPECT_EQ(S_IFREG | newmode, sb.st_mode); } /* Change the owner and group of a file */ TEST_F(Setattr, chown) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const uint64_t ino = 42; const gid_t oldgroup = 66; const gid_t newgroup = 99; const uid_t olduser = 33; const uid_t newuser = 44; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | 0644; out.body.entry.nodeid = ino; out.body.entry.attr.gid = oldgroup; out.body.entry.attr.uid = olduser; }))); EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { uint32_t valid = FATTR_GID | FATTR_UID; return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && in.body.setattr.valid == valid && in.body.setattr.uid == newuser && in.body.setattr.gid == newgroup); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; // Must match nodeid out.body.attr.attr.mode = S_IFREG | 0644; out.body.attr.attr.uid = newuser; out.body.attr.attr.gid = newgroup; }))); EXPECT_EQ(0, chown(FULLPATH, newuser, newgroup)) << strerror(errno); } /* * FUSE daemons are allowed to check permissions however they like. If the * daemon returns EPERM, even if the file permissions "should" grant access, * then fuse(4) should return EPERM too. */ TEST_F(Setattr, eperm) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const uint64_t ino = 42; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | 0777; out.body.entry.nodeid = ino; out.body.entry.attr.uid = in.header.uid; out.body.entry.attr.gid = in.header.gid; }))); EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino); }, Eq(true)), _) ).WillOnce(Invoke(ReturnErrno(EPERM))); EXPECT_NE(0, truncate(FULLPATH, 10)); EXPECT_EQ(EPERM, errno); } /* Change the mode of an open file, by its file descriptor */ TEST_F(Setattr, fchmod) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; uint64_t ino = 42; int fd; const mode_t oldmode = 0755; const mode_t newmode = 0644; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | oldmode; out.body.entry.nodeid = ino; out.body.entry.attr_valid = UINT64_MAX; }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_OPEN && in.header.nodeid == ino); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { out.header.len = sizeof(out.header); SET_OUT_HEADER_LEN(out, open); }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { uint32_t valid = FATTR_MODE; return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && in.body.setattr.valid == valid && in.body.setattr.mode == newmode); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; // Must match nodeid out.body.attr.attr.mode = S_IFREG | newmode; }))); fd = open(FULLPATH, O_RDONLY); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(0, fchmod(fd, newmode)) << strerror(errno); leak(fd); } /* Change the size of an open file, by its file descriptor */ TEST_F(Setattr, ftruncate) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; uint64_t ino = 42; int fd; uint64_t fh = 0xdeadbeef1a7ebabe; const off_t oldsize = 99; const off_t newsize = 12345; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | 0755; out.body.entry.nodeid = ino; out.body.entry.attr_valid = UINT64_MAX; out.body.entry.attr.size = oldsize; }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_OPEN && in.header.nodeid == ino); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { out.header.len = sizeof(out.header); SET_OUT_HEADER_LEN(out, open); out.body.open.fh = fh; }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { uint32_t valid = FATTR_SIZE | FATTR_FH; return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && in.body.setattr.valid == valid && in.body.setattr.fh == fh); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; // Must match nodeid out.body.attr.attr.mode = S_IFREG | 0755; out.body.attr.attr.size = newsize; }))); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(0, ftruncate(fd, newsize)) << strerror(errno); leak(fd); } /* Change the size of the file */ TEST_F(Setattr, truncate) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const uint64_t ino = 42; const uint64_t oldsize = 100'000'000; const uint64_t newsize = 20'000'000; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | 0644; out.body.entry.nodeid = ino; out.body.entry.attr.size = oldsize; }))); EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { uint32_t valid = FATTR_SIZE; return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && in.body.setattr.valid == valid && in.body.setattr.size == newsize); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; // Must match nodeid out.body.attr.attr.mode = S_IFREG | 0644; out.body.attr.attr.size = newsize; }))); EXPECT_EQ(0, truncate(FULLPATH, newsize)) << strerror(errno); } /* * Truncating a file should discard cached data past the truncation point. * This is a regression test for bug 233783. * * There are two distinct failure modes. The first one is a failure to zero * the portion of the file's final buffer past EOF. It can be reproduced by * fsx -WR -P /tmp -S10 fsx.bin * * The second is a failure to drop buffers beyond that. It can be reproduced by * fsx -WR -P /tmp -S18 -n fsx.bin * Also reproducible in sh with: * $> /path/to/libfuse/build/example/passthrough -d /tmp/mnt * $> cd /tmp/mnt/tmp * $> dd if=/dev/random of=randfile bs=1k count=192 * $> truncate -s 1k randfile && truncate -s 192k randfile * $> xxd randfile | less # xxd will wrongly show random data at offset 0x8000 */ TEST_F(Setattr, truncate_discards_cached_data) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; void *w0buf, *r0buf, *r1buf, *expected; off_t w0_offset = 0; size_t w0_size = 0x30000; off_t r0_offset = 0; off_t r0_size = w0_size; size_t trunc0_size = 0x400; size_t trunc1_size = w0_size; off_t r1_offset = trunc0_size; off_t r1_size = w0_size - trunc0_size; size_t cur_size = 0; const uint64_t ino = 42; mode_t mode = S_IFREG | 0644; int fd, r; bool should_have_data = false; w0buf = malloc(w0_size); ASSERT_NE(nullptr, w0buf) << strerror(errno); memset(w0buf, 'X', w0_size); r0buf = malloc(r0_size); ASSERT_NE(nullptr, r0buf) << strerror(errno); r1buf = malloc(r1_size); ASSERT_NE(nullptr, r1buf) << strerror(errno); expected = malloc(r1_size); ASSERT_NE(nullptr, expected) << strerror(errno); memset(expected, 0, r1_size); expect_lookup(RELPATH, ino, mode, 0, 1); expect_open(ino, O_RDWR, 1); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_GETATTR && in.header.nodeid == ino); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnImmediate([&](auto i __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; out.body.attr.attr.mode = mode; out.body.attr.attr.size = cur_size; }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_WRITE); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnImmediate([&](auto in, auto& out) { SET_OUT_HEADER_LEN(out, write); out.body.attr.attr.ino = ino; out.body.write.size = in.body.write.size; cur_size = std::max(static_cast(cur_size), in.body.write.size + in.body.write.offset); }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && (in.body.setattr.valid & FATTR_SIZE)); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnImmediate([&](auto in, auto& out) { auto trunc_size = in.body.setattr.size; SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; out.body.attr.attr.mode = mode; out.body.attr.attr.size = trunc_size; cur_size = trunc_size; }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_READ); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnImmediate([&](auto in, auto& out) { auto osize = std::min( static_cast(cur_size) - in.body.read.offset, static_cast(in.body.read.size)); + assert(osize <= sizeof(out.body.bytes)); out.header.len = sizeof(struct fuse_out_header) + osize; if (should_have_data) memset(out.body.bytes, 'X', osize); else bzero(out.body.bytes, osize); }))); fd = open(FULLPATH, O_RDWR, 0644); ASSERT_LE(0, fd) << strerror(errno); /* Fill the file with Xs */ ASSERT_EQ(static_cast(w0_size), pwrite(fd, w0buf, w0_size, w0_offset)); should_have_data = true; /* Fill the cache */ ASSERT_EQ(static_cast(r0_size), pread(fd, r0buf, r0_size, r0_offset)); /* 1st truncate should discard cached data */ EXPECT_EQ(0, ftruncate(fd, trunc0_size)) << strerror(errno); should_have_data = false; /* 2nd truncate extends file into previously cached data */ EXPECT_EQ(0, ftruncate(fd, trunc1_size)) << strerror(errno); /* Read should return all zeros */ ASSERT_EQ(static_cast(r1_size), pread(fd, r1buf, r1_size, r1_offset)); r = memcmp(expected, r1buf, r1_size); ASSERT_EQ(0, r); free(expected); free(r1buf); free(r0buf); free(w0buf); leak(fd); } /* truncate should fail if it would cause the file to exceed RLIMIT_FSIZE */ TEST_F(Setattr, truncate_rlimit_rsize) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; struct rlimit rl; const uint64_t ino = 42; const uint64_t oldsize = 0; const uint64_t newsize = 100'000'000; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | 0644; out.body.entry.nodeid = ino; out.body.entry.attr.size = oldsize; }))); rl.rlim_cur = newsize / 2; rl.rlim_max = 10 * newsize; ASSERT_EQ(0, setrlimit(RLIMIT_FSIZE, &rl)) << strerror(errno); ASSERT_NE(SIG_ERR, signal(SIGXFSZ, sigxfsz_handler)) << strerror(errno); EXPECT_EQ(-1, truncate(FULLPATH, newsize)); EXPECT_EQ(EFBIG, errno); EXPECT_EQ(1, s_sigxfsz); } /* Change a file's timestamps */ TEST_F(Setattr, utimensat) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const uint64_t ino = 42; const timespec oldtimes[2] = { {.tv_sec = 1, .tv_nsec = 2}, {.tv_sec = 3, .tv_nsec = 4}, }; const timespec newtimes[2] = { {.tv_sec = 5, .tv_nsec = 6}, {.tv_sec = 7, .tv_nsec = 8}, }; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | 0644; out.body.entry.nodeid = ino; out.body.entry.attr_valid = UINT64_MAX; out.body.entry.attr.atime = oldtimes[0].tv_sec; out.body.entry.attr.atimensec = oldtimes[0].tv_nsec; out.body.entry.attr.mtime = oldtimes[1].tv_sec; out.body.entry.attr.mtimensec = oldtimes[1].tv_nsec; }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { uint32_t valid = FATTR_ATIME | FATTR_MTIME; return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && in.body.setattr.valid == valid && (time_t)in.body.setattr.atime == newtimes[0].tv_sec && (long)in.body.setattr.atimensec == newtimes[0].tv_nsec && (time_t)in.body.setattr.mtime == newtimes[1].tv_sec && (long)in.body.setattr.mtimensec == newtimes[1].tv_nsec); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; // Must match nodeid out.body.attr.attr.mode = S_IFREG | 0644; out.body.attr.attr.atime = newtimes[0].tv_sec; out.body.attr.attr.atimensec = newtimes[0].tv_nsec; out.body.attr.attr.mtime = newtimes[1].tv_sec; out.body.attr.attr.mtimensec = newtimes[1].tv_nsec; }))); EXPECT_EQ(0, utimensat(AT_FDCWD, FULLPATH, &newtimes[0], 0)) << strerror(errno); } /* Change a file mtime but not its atime */ TEST_F(Setattr, utimensat_mtime_only) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const uint64_t ino = 42; const timespec oldtimes[2] = { {.tv_sec = 1, .tv_nsec = 2}, {.tv_sec = 3, .tv_nsec = 4}, }; const timespec newtimes[2] = { {.tv_sec = 5, .tv_nsec = UTIME_OMIT}, {.tv_sec = 7, .tv_nsec = 8}, }; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | 0644; out.body.entry.nodeid = ino; out.body.entry.attr_valid = UINT64_MAX; out.body.entry.attr.atime = oldtimes[0].tv_sec; out.body.entry.attr.atimensec = oldtimes[0].tv_nsec; out.body.entry.attr.mtime = oldtimes[1].tv_sec; out.body.entry.attr.mtimensec = oldtimes[1].tv_nsec; }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { uint32_t valid = FATTR_MTIME; return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && in.body.setattr.valid == valid && (time_t)in.body.setattr.mtime == newtimes[1].tv_sec && (long)in.body.setattr.mtimensec == newtimes[1].tv_nsec); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; // Must match nodeid out.body.attr.attr.mode = S_IFREG | 0644; out.body.attr.attr.atime = oldtimes[0].tv_sec; out.body.attr.attr.atimensec = oldtimes[0].tv_nsec; out.body.attr.attr.mtime = newtimes[1].tv_sec; out.body.attr.attr.mtimensec = newtimes[1].tv_nsec; }))); EXPECT_EQ(0, utimensat(AT_FDCWD, FULLPATH, &newtimes[0], 0)) << strerror(errno); } /* * Set a file's mtime and atime to now * * The design of FreeBSD's VFS does not allow fusefs to set just one of atime * or mtime to UTIME_NOW; it's both or neither. */ TEST_F(Setattr, utimensat_utime_now) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const uint64_t ino = 42; const timespec oldtimes[2] = { {.tv_sec = 1, .tv_nsec = 2}, {.tv_sec = 3, .tv_nsec = 4}, }; const timespec newtimes[2] = { {.tv_sec = 0, .tv_nsec = UTIME_NOW}, {.tv_sec = 0, .tv_nsec = UTIME_NOW}, }; /* "now" is whatever the server says it is */ const timespec now[2] = { {.tv_sec = 5, .tv_nsec = 7}, {.tv_sec = 6, .tv_nsec = 8}, }; struct stat sb; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | 0644; out.body.entry.nodeid = ino; out.body.entry.attr_valid = UINT64_MAX; out.body.entry.entry_valid = UINT64_MAX; out.body.entry.attr.atime = oldtimes[0].tv_sec; out.body.entry.attr.atimensec = oldtimes[0].tv_nsec; out.body.entry.attr.mtime = oldtimes[1].tv_sec; out.body.entry.attr.mtimensec = oldtimes[1].tv_nsec; }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { uint32_t valid = FATTR_ATIME | FATTR_ATIME_NOW | FATTR_MTIME | FATTR_MTIME_NOW; return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && in.body.setattr.valid == valid); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; // Must match nodeid out.body.attr.attr.mode = S_IFREG | 0644; out.body.attr.attr.atime = now[0].tv_sec; out.body.attr.attr.atimensec = now[0].tv_nsec; out.body.attr.attr.mtime = now[1].tv_sec; out.body.attr.attr.mtimensec = now[1].tv_nsec; out.body.attr.attr_valid = UINT64_MAX; }))); ASSERT_EQ(0, utimensat(AT_FDCWD, FULLPATH, &newtimes[0], 0)) << strerror(errno); ASSERT_EQ(0, stat(FULLPATH, &sb)) << strerror(errno); EXPECT_EQ(now[0].tv_sec, sb.st_atim.tv_sec); EXPECT_EQ(now[0].tv_nsec, sb.st_atim.tv_nsec); EXPECT_EQ(now[1].tv_sec, sb.st_mtim.tv_sec); EXPECT_EQ(now[1].tv_nsec, sb.st_mtim.tv_nsec); } /* * FUSE_SETATTR returns a different file type, even though the entry cache * hasn't expired. This is a server bug! It probably means that the server * removed the file and recreated it with the same inode but a different vtyp. * The best thing fusefs can do is return ENOENT to the caller. After all, the * entry must not have existed recently. */ TEST_F(Setattr, vtyp_conflict) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const uint64_t ino = 42; uid_t newuser = 12345; sem_t sem; ASSERT_EQ(0, sem_init(&sem, 0, 0)) << strerror(errno); EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | 0777; out.body.entry.nodeid = ino; out.body.entry.entry_valid = UINT64_MAX; }))); EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; out.body.attr.attr.mode = S_IFDIR | 0777; // Changed! out.body.attr.attr.uid = newuser; }))); // We should reclaim stale vnodes expect_forget(ino, 1, &sem); EXPECT_NE(0, chown(FULLPATH, newuser, -1)); EXPECT_EQ(ENOENT, errno); sem_wait(&sem); sem_destroy(&sem); } /* On a read-only mount, no attributes may be changed */ TEST_F(RofsSetattr, erofs) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const uint64_t ino = 42; const mode_t oldmode = 0755; const mode_t newmode = 0644; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | oldmode; out.body.entry.nodeid = ino; }))); ASSERT_EQ(-1, chmod(FULLPATH, newmode)); ASSERT_EQ(EROFS, errno); } /* Change the mode of a file */ TEST_F(Setattr_7_8, chmod) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const uint64_t ino = 42; const mode_t oldmode = 0755; const mode_t newmode = 0644; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry_7_8); out.body.entry.attr.mode = S_IFREG | oldmode; out.body.entry.nodeid = ino; }))); EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { uint32_t valid = FATTR_MODE; return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && in.body.setattr.valid == valid && in.body.setattr.mode == newmode); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr_7_8); out.body.attr.attr.ino = ino; // Must match nodeid out.body.attr.attr.mode = S_IFREG | newmode; }))); EXPECT_EQ(0, chmod(FULLPATH, newmode)) << strerror(errno); } diff --git a/tests/sys/fs/fusefs/utils.cc b/tests/sys/fs/fusefs/utils.cc index d4edca5ca945..b13ecfd9cb88 100644 --- a/tests/sys/fs/fusefs/utils.cc +++ b/tests/sys/fs/fusefs/utils.cc @@ -1,676 +1,682 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2019 The FreeBSD Foundation * * This software was developed by BFF Storage Systems, LLC under sponsorship * from the FreeBSD Foundation. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD$ */ extern "C" { #include #include #include #include #include #include #include #include #include #include #include } #include #include "mockfs.hh" #include "utils.hh" using namespace testing; /* * The default max_write is set to this formula in libfuse, though * individual filesystems can lower it. The "- 4096" was added in * commit 154ffe2, with the commit message "fix". */ const uint32_t libfuse_max_write = 32 * getpagesize() + 0x1000 - 4096; /* Check that fusefs(4) is accessible and the current user can mount(2) */ void check_environment() { const char *devnode = "/dev/fuse"; const char *bsdextended_node = "security.mac.bsdextended.enabled"; int bsdextended_val = 0; size_t bsdextended_size = sizeof(bsdextended_val); int bsdextended_found; const char *usermount_node = "vfs.usermount"; int usermount_val = 0; size_t usermount_size = sizeof(usermount_val); if (eaccess(devnode, R_OK | W_OK)) { if (errno == ENOENT) { GTEST_SKIP() << devnode << " does not exist"; } else if (errno == EACCES) { GTEST_SKIP() << devnode << " is not accessible by the current user"; } else { GTEST_SKIP() << strerror(errno); } } // mac_bsdextended(4), when enabled, generates many more GETATTR // operations. The fusefs tests' expectations don't account for those, // and adding extra code to handle them obfuscates the real purpose of // the tests. Better just to skip the fusefs tests if mac_bsdextended // is enabled. bsdextended_found = sysctlbyname(bsdextended_node, &bsdextended_val, &bsdextended_size, NULL, 0); if (bsdextended_found == 0 && bsdextended_val != 0) GTEST_SKIP() << "The fusefs tests are incompatible with mac_bsdextended."; ASSERT_EQ(sysctlbyname(usermount_node, &usermount_val, &usermount_size, NULL, 0), 0); if (geteuid() != 0 && !usermount_val) GTEST_SKIP() << "current user is not allowed to mount"; } const char *cache_mode_to_s(enum cache_mode cm) { switch (cm) { case Uncached: return "Uncached"; case Writethrough: return "Writethrough"; case Writeback: return "Writeback"; case WritebackAsync: return "WritebackAsync"; default: return "Unknown"; } } bool is_unsafe_aio_enabled(void) { const char *node = "vfs.aio.enable_unsafe"; int val = 0; size_t size = sizeof(val); if (sysctlbyname(node, &val, &size, NULL, 0)) { perror("sysctlbyname"); return (false); } return (val != 0); } class FuseEnv: public Environment { virtual void SetUp() { } }; void FuseTest::SetUp() { const char *maxbcachebuf_node = "vfs.maxbcachebuf"; const char *maxphys_node = "kern.maxphys"; int val = 0; size_t size = sizeof(val); /* * XXX check_environment should be called from FuseEnv::SetUp, but * can't due to https://github.com/google/googletest/issues/2189 */ check_environment(); if (IsSkipped()) return; ASSERT_EQ(0, sysctlbyname(maxbcachebuf_node, &val, &size, NULL, 0)) << strerror(errno); m_maxbcachebuf = val; ASSERT_EQ(0, sysctlbyname(maxphys_node, &val, &size, NULL, 0)) << strerror(errno); m_maxphys = val; /* * Set the default max_write to a distinct value from MAXPHYS to catch * bugs that confuse the two. */ if (m_maxwrite == 0) m_maxwrite = MIN(libfuse_max_write, (uint32_t)m_maxphys / 2); try { m_mock = new MockFS(m_maxreadahead, m_allow_other, m_default_permissions, m_push_symlinks_in, m_ro, m_pm, m_init_flags, m_kernel_minor_version, m_maxwrite, m_async, m_noclusterr, m_time_gran, m_nointr, m_noatime, m_fsname, m_subtype); /* * FUSE_ACCESS is called almost universally. Expecting it in * each test case would be super-annoying. Instead, set a * default expectation for FUSE_ACCESS and return ENOSYS. * * Individual test cases can override this expectation since * googlemock evaluates expectations in LIFO order. */ EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_ACCESS); }, Eq(true)), _) ).Times(AnyNumber()) .WillRepeatedly(Invoke(ReturnErrno(ENOSYS))); /* * FUSE_BMAP is called for most test cases that read data. Set * a default expectation and return ENOSYS. * * Individual test cases can override this expectation since * googlemock evaluates expectations in LIFO order. */ EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_BMAP); }, Eq(true)), _) ).Times(AnyNumber()) .WillRepeatedly(Invoke(ReturnErrno(ENOSYS))); } catch (std::system_error err) { FAIL() << err.what(); } } void FuseTest::expect_access(uint64_t ino, mode_t access_mode, int error) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_ACCESS && in.header.nodeid == ino && in.body.access.mask == access_mode); }, Eq(true)), _) ).WillOnce(Invoke(ReturnErrno(error))); } void FuseTest::expect_destroy(int error) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_DESTROY); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in, auto& out) { m_mock->m_quit = true; out.header.len = sizeof(out.header); out.header.unique = in.header.unique; out.header.error = -error; }))); } void FuseTest::expect_fallocate(uint64_t ino, uint64_t offset, uint64_t length, uint32_t mode, int error, int times) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_FALLOCATE && in.header.nodeid == ino && in.body.fallocate.offset == offset && in.body.fallocate.length == length && in.body.fallocate.mode == mode); }, Eq(true)), _) ).Times(times) .WillRepeatedly(Invoke(ReturnErrno(error))); } void FuseTest::expect_flush(uint64_t ino, int times, ProcessMockerT r) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_FLUSH && in.header.nodeid == ino); }, Eq(true)), _) ).Times(times) .WillRepeatedly(Invoke(r)); } void FuseTest::expect_forget(uint64_t ino, uint64_t nlookup, sem_t *sem) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_FORGET && in.header.nodeid == ino && in.body.forget.nlookup == nlookup); }, Eq(true)), _) ).WillOnce(Invoke([=](auto in __unused, auto &out __unused) { if (sem != NULL) sem_post(sem); /* FUSE_FORGET has no response! */ })); } void FuseTest::expect_getattr(uint64_t ino, uint64_t size) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_GETATTR && in.header.nodeid == ino); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto i __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; // Must match nodeid out.body.attr.attr.mode = S_IFREG | 0644; out.body.attr.attr.size = size; out.body.attr.attr_valid = UINT64_MAX; }))); } void FuseTest::expect_getxattr(uint64_t ino, const char *attr, ProcessMockerT r) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { const char *a = (const char*)in.body.bytes + sizeof(fuse_getxattr_in); return (in.header.opcode == FUSE_GETXATTR && in.header.nodeid == ino && 0 == strcmp(attr, a)); }, Eq(true)), _) ).WillOnce(Invoke(r)); } void FuseTest::expect_lookup(const char *relpath, uint64_t ino, mode_t mode, uint64_t size, int times, uint64_t attr_valid, uid_t uid, gid_t gid) { EXPECT_LOOKUP(FUSE_ROOT_ID, relpath) .Times(times) .WillRepeatedly(Invoke( ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = mode; out.body.entry.nodeid = ino; out.body.entry.attr.nlink = 1; out.body.entry.attr_valid = attr_valid; out.body.entry.attr.size = size; out.body.entry.attr.uid = uid; out.body.entry.attr.gid = gid; }))); } void FuseTest::expect_lookup_7_8(const char *relpath, uint64_t ino, mode_t mode, uint64_t size, int times, uint64_t attr_valid, uid_t uid, gid_t gid) { EXPECT_LOOKUP(FUSE_ROOT_ID, relpath) .Times(times) .WillRepeatedly(Invoke( ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry_7_8); out.body.entry.attr.mode = mode; out.body.entry.nodeid = ino; out.body.entry.attr.nlink = 1; out.body.entry.attr_valid = attr_valid; out.body.entry.attr.size = size; out.body.entry.attr.uid = uid; out.body.entry.attr.gid = gid; }))); } void FuseTest::expect_open(uint64_t ino, uint32_t flags, int times) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_OPEN && in.header.nodeid == ino); }, Eq(true)), _) ).Times(times) .WillRepeatedly(Invoke( ReturnImmediate([=](auto in __unused, auto& out) { out.header.len = sizeof(out.header); SET_OUT_HEADER_LEN(out, open); out.body.open.fh = FH; out.body.open.open_flags = flags; }))); } void FuseTest::expect_opendir(uint64_t ino) { /* opendir(3) calls fstatfs */ EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { return (in.header.opcode == FUSE_STATFS); }, Eq(true)), _) ).WillRepeatedly(Invoke( ReturnImmediate([=](auto i __unused, auto& out) { SET_OUT_HEADER_LEN(out, statfs); }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_OPENDIR && in.header.nodeid == ino); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { out.header.len = sizeof(out.header); SET_OUT_HEADER_LEN(out, open); out.body.open.fh = FH; }))); } void FuseTest::expect_read(uint64_t ino, uint64_t offset, uint64_t isize, uint64_t osize, const void *contents, int flags, uint64_t fh) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_READ && in.header.nodeid == ino && in.body.read.fh == fh && in.body.read.offset == offset && in.body.read.size == isize && (flags == -1 ? (in.body.read.flags == O_RDONLY || in.body.read.flags == O_RDWR) : in.body.read.flags == (uint32_t)flags)); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { + assert(osize <= sizeof(out.body.bytes)); out.header.len = sizeof(struct fuse_out_header) + osize; memmove(out.body.bytes, contents, osize); }))).RetiresOnSaturation(); } void FuseTest::expect_readdir(uint64_t ino, uint64_t off, std::vector &ents) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_READDIR && in.header.nodeid == ino && in.body.readdir.fh == FH && in.body.readdir.offset == off); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnImmediate([=](auto in, auto& out) { struct fuse_dirent *fde = (struct fuse_dirent*)&(out.body); int i = 0; out.header.error = 0; out.header.len = 0; for (const auto& it: ents) { size_t entlen, entsize; fde->ino = it.d_fileno; fde->off = it.d_off; fde->type = it.d_type; fde->namelen = it.d_namlen; strncpy(fde->name, it.d_name, it.d_namlen); entlen = FUSE_NAME_OFFSET + fde->namelen; entsize = FUSE_DIRENT_SIZE(fde); /* * The FUSE protocol does not require zeroing out the * unused portion of the name. But it's a good * practice to prevent information disclosure to the * FUSE client, even though the client is usually the * kernel */ memset(fde->name + fde->namelen, 0, entsize - entlen); if (out.header.len + entsize > in.body.read.size) { printf("Overflow in readdir expectation: i=%d\n" , i); break; } out.header.len += entsize; fde = (struct fuse_dirent*) ((intmax_t*)fde + entsize / sizeof(intmax_t)); i++; } out.header.len += sizeof(out.header); }))); } void FuseTest::expect_release(uint64_t ino, uint64_t fh) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_RELEASE && in.header.nodeid == ino && in.body.release.fh == fh); }, Eq(true)), _) ).WillOnce(Invoke(ReturnErrno(0))); } void FuseTest::expect_releasedir(uint64_t ino, ProcessMockerT r) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_RELEASEDIR && in.header.nodeid == ino && in.body.release.fh == FH); }, Eq(true)), _) ).WillOnce(Invoke(r)); } void FuseTest::expect_unlink(uint64_t parent, const char *path, int error) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_UNLINK && 0 == strcmp(path, in.body.unlink) && in.header.nodeid == parent); }, Eq(true)), _) ).WillOnce(Invoke(ReturnErrno(error))); } void FuseTest::expect_write(uint64_t ino, uint64_t offset, uint64_t isize, uint64_t osize, uint32_t flags_set, uint32_t flags_unset, const void *contents) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { const char *buf = (const char*)in.body.bytes + sizeof(struct fuse_write_in); bool pid_ok; uint32_t wf = in.body.write.write_flags; + assert(isize <= sizeof(in.body.bytes) - + sizeof(struct fuse_write_in)); if (wf & FUSE_WRITE_CACHE) pid_ok = true; else pid_ok = (pid_t)in.header.pid == getpid(); return (in.header.opcode == FUSE_WRITE && in.header.nodeid == ino && in.body.write.fh == FH && in.body.write.offset == offset && in.body.write.size == isize && pid_ok && (wf & flags_set) == flags_set && (wf & flags_unset) == 0 && (in.body.write.flags == O_WRONLY || in.body.write.flags == O_RDWR) && 0 == bcmp(buf, contents, isize)); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, write); out.body.write.size = osize; }))); } void FuseTest::expect_write_7_8(uint64_t ino, uint64_t offset, uint64_t isize, uint64_t osize, const void *contents) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { const char *buf = (const char*)in.body.bytes + FUSE_COMPAT_WRITE_IN_SIZE; bool pid_ok = (pid_t)in.header.pid == getpid(); + + assert(isize <= sizeof(in.body.bytes) - + FUSE_COMPAT_WRITE_IN_SIZE); return (in.header.opcode == FUSE_WRITE && in.header.nodeid == ino && in.body.write.fh == FH && in.body.write.offset == offset && in.body.write.size == isize && pid_ok && 0 == bcmp(buf, contents, isize)); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, write); out.body.write.size = osize; }))); } void get_unprivileged_id(uid_t *uid, gid_t *gid) { struct passwd *pw; struct group *gr; /* * First try "tests", Kyua's default unprivileged user. XXX after * GoogleTest gains a proper Kyua wrapper, get this with the Kyua API */ pw = getpwnam("tests"); if (pw == NULL) { /* Fall back to "nobody" */ pw = getpwnam("nobody"); } if (pw == NULL) GTEST_SKIP() << "Test requires an unprivileged user"; /* Use group "nobody", which is Kyua's default unprivileged group */ gr = getgrnam("nobody"); if (gr == NULL) GTEST_SKIP() << "Test requires an unprivileged group"; *uid = pw->pw_uid; *gid = gr->gr_gid; } void FuseTest::fork(bool drop_privs, int *child_status, std::function parent_func, std::function child_func) { sem_t *sem; int mprot = PROT_READ | PROT_WRITE; int mflags = MAP_ANON | MAP_SHARED; pid_t child; uid_t uid; gid_t gid; if (drop_privs) { get_unprivileged_id(&uid, &gid); if (IsSkipped()) return; } sem = (sem_t*)mmap(NULL, sizeof(*sem), mprot, mflags, -1, 0); ASSERT_NE(MAP_FAILED, sem) << strerror(errno); ASSERT_EQ(0, sem_init(sem, 1, 0)) << strerror(errno); if ((child = ::fork()) == 0) { /* In child */ int err = 0; if (sem_wait(sem)) { perror("sem_wait"); err = 1; goto out; } if (drop_privs && 0 != setegid(gid)) { perror("setegid"); err = 1; goto out; } if (drop_privs && 0 != setreuid(-1, uid)) { perror("setreuid"); err = 1; goto out; } err = child_func(); out: sem_destroy(sem); _exit(err); } else if (child > 0) { /* * In parent. Cleanup must happen here, because it's still * privileged. */ m_mock->m_child_pid = child; ASSERT_NO_FATAL_FAILURE(parent_func()); /* Signal the child process to go */ ASSERT_EQ(0, sem_post(sem)) << strerror(errno); ASSERT_LE(0, wait(child_status)) << strerror(errno); } else { FAIL() << strerror(errno); } munmap(sem, sizeof(*sem)); return; } void FuseTest::reclaim_vnode(const char *path) { int err; err = sysctlbyname(reclaim_mib, NULL, 0, path, strlen(path) + 1); ASSERT_EQ(0, err) << strerror(errno); } static void usage(char* progname) { fprintf(stderr, "Usage: %s [-v]\n\t-v increase verbosity\n", progname); exit(2); } int main(int argc, char **argv) { int ch; FuseEnv *fuse_env = new FuseEnv; InitGoogleTest(&argc, argv); AddGlobalTestEnvironment(fuse_env); while ((ch = getopt(argc, argv, "v")) != -1) { switch (ch) { case 'v': verbosity++; break; default: usage(argv[0]); break; } } return (RUN_ALL_TESTS()); } diff --git a/tests/sys/fs/fusefs/write.cc b/tests/sys/fs/fusefs/write.cc index 4e76414a601a..800376395e97 100644 --- a/tests/sys/fs/fusefs/write.cc +++ b/tests/sys/fs/fusefs/write.cc @@ -1,1602 +1,1604 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2019 The FreeBSD Foundation * * This software was developed by BFF Storage Systems, LLC under sponsorship * from the FreeBSD Foundation. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD$ */ extern "C" { #include #include #include #include #include #include #include #include #include #include } #include "mockfs.hh" #include "utils.hh" using namespace testing; class Write: public FuseTest { public: void SetUp() { FuseTest::SetUp(); } void TearDown() { struct sigaction sa; bzero(&sa, sizeof(sa)); sa.sa_handler = SIG_DFL; sigaction(SIGXFSZ, &sa, NULL); FuseTest::TearDown(); } void expect_lookup(const char *relpath, uint64_t ino, uint64_t size) { FuseTest::expect_lookup(relpath, ino, S_IFREG | 0644, size, 1); } void expect_release(uint64_t ino, ProcessMockerT r) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_RELEASE && in.header.nodeid == ino); }, Eq(true)), _) ).WillRepeatedly(Invoke(r)); } void expect_write(uint64_t ino, uint64_t offset, uint64_t isize, uint64_t osize, const void *contents) { FuseTest::expect_write(ino, offset, isize, osize, 0, 0, contents); } /* Expect a write that may or may not come, depending on the cache mode */ void maybe_expect_write(uint64_t ino, uint64_t offset, uint64_t size, const void *contents) { EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { const char *buf = (const char*)in.body.bytes + sizeof(struct fuse_write_in); + assert(size <= sizeof(in.body.bytes) - + sizeof(struct fuse_write_in)); return (in.header.opcode == FUSE_WRITE && in.header.nodeid == ino && in.body.write.offset == offset && in.body.write.size == size && 0 == bcmp(buf, contents, size)); }, Eq(true)), _) ).Times(AtMost(1)) .WillRepeatedly(Invoke( ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, write); out.body.write.size = size; }) )); } }; class Write_7_8: public FuseTest { public: virtual void SetUp() { m_kernel_minor_version = 8; FuseTest::SetUp(); } void expect_lookup(const char *relpath, uint64_t ino, uint64_t size) { FuseTest::expect_lookup_7_8(relpath, ino, S_IFREG | 0644, size, 1); } }; class AioWrite: public Write { virtual void SetUp() { if (!is_unsafe_aio_enabled()) GTEST_SKIP() << "vfs.aio.enable_unsafe must be set for this test"; FuseTest::SetUp(); } }; /* Tests for the writeback cache mode */ class WriteBack: public Write { public: virtual void SetUp() { m_init_flags |= FUSE_WRITEBACK_CACHE; FuseTest::SetUp(); if (IsSkipped()) return; } void expect_write(uint64_t ino, uint64_t offset, uint64_t isize, uint64_t osize, const void *contents) { FuseTest::expect_write(ino, offset, isize, osize, FUSE_WRITE_CACHE, 0, contents); } }; class WriteBackAsync: public WriteBack { public: virtual void SetUp() { m_async = true; m_maxwrite = 65536; WriteBack::SetUp(); } }; class TimeGran: public WriteBackAsync, public WithParamInterface { public: virtual void SetUp() { m_time_gran = 1 << GetParam(); WriteBackAsync::SetUp(); } }; /* Tests for clustered writes with WriteBack cacheing */ class WriteCluster: public WriteBack { public: virtual void SetUp() { m_async = true; m_maxwrite = 1 << 25; // Anything larger than MAXPHYS will suffice WriteBack::SetUp(); if (m_maxphys < 2 * DFLTPHYS) GTEST_SKIP() << "MAXPHYS must be at least twice DFLTPHYS" << " for this test"; if (m_maxphys < 2 * m_maxbcachebuf) GTEST_SKIP() << "MAXPHYS must be at least twice maxbcachebuf" << " for this test"; } }; /* Tests relating to the server's max_write property */ class WriteMaxWrite: public Write { public: virtual void SetUp() { /* * For this test, m_maxwrite must be less than either m_maxbcachebuf or * maxphys. */ m_maxwrite = 32768; Write::SetUp(); } }; class WriteEofDuringVnopStrategy: public Write, public WithParamInterface {}; class WriteRlimitFsize: public Write, public WithParamInterface { public: static sig_atomic_t s_sigxfsz; struct rlimit m_initial_limit; void SetUp() { s_sigxfsz = 0; getrlimit(RLIMIT_FSIZE, &m_initial_limit); FuseTest::SetUp(); } void TearDown() { setrlimit(RLIMIT_FSIZE, &m_initial_limit); FuseTest::TearDown(); } }; sig_atomic_t WriteRlimitFsize::s_sigxfsz = 0; void sigxfsz_handler(int __unused sig) { WriteRlimitFsize::s_sigxfsz = 1; } /* AIO writes need to set the header's pid field correctly */ /* https://bugs.freebsd.org/bugzilla/show_bug.cgi?id=236379 */ TEST_F(AioWrite, DISABLED_aio_write) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; uint64_t ino = 42; uint64_t offset = 4096; int fd; ssize_t bufsize = strlen(CONTENTS); struct aiocb iocb, *piocb; expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); expect_write(ino, offset, bufsize, bufsize, CONTENTS); fd = open(FULLPATH, O_WRONLY); ASSERT_LE(0, fd) << strerror(errno); iocb.aio_nbytes = bufsize; iocb.aio_fildes = fd; iocb.aio_buf = __DECONST(void *, CONTENTS); iocb.aio_offset = offset; iocb.aio_sigevent.sigev_notify = SIGEV_NONE; ASSERT_EQ(0, aio_write(&iocb)) << strerror(errno); ASSERT_EQ(bufsize, aio_waitcomplete(&piocb, NULL)) << strerror(errno); leak(fd); } /* * When a file is opened with O_APPEND, we should forward that flag to * FUSE_OPEN (tested by Open.o_append) but still attempt to calculate the * offset internally. That way we'll work both with filesystems that * understand O_APPEND (and ignore the offset) and filesystems that don't (and * simply use the offset). * * Note that verifying the O_APPEND flag in FUSE_OPEN is done in the * Open.o_append test. */ TEST_F(Write, append) { const ssize_t BUFSIZE = 9; const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char CONTENTS[BUFSIZE] = "abcdefgh"; uint64_t ino = 42; /* * Set offset to a maxbcachebuf boundary so we don't need to RMW when * using writeback caching */ uint64_t initial_offset = m_maxbcachebuf; int fd; expect_lookup(RELPATH, ino, initial_offset); expect_open(ino, 0, 1); expect_write(ino, initial_offset, BUFSIZE, BUFSIZE, CONTENTS); /* Must open O_RDWR or fuse(4) implicitly sets direct_io */ fd = open(FULLPATH, O_RDWR | O_APPEND); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(BUFSIZE, write(fd, CONTENTS, BUFSIZE)) << strerror(errno); leak(fd); } /* If a file is cached, then appending to the end should not cause a read */ TEST_F(Write, append_to_cached) { const ssize_t BUFSIZE = 9; const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; char *oldcontents, *oldbuf; const char CONTENTS[BUFSIZE] = "abcdefgh"; uint64_t ino = 42; /* * Set offset in between maxbcachebuf boundary to test buffer handling */ uint64_t oldsize = m_maxbcachebuf / 2; int fd; oldcontents = (char*)calloc(1, oldsize); ASSERT_NE(nullptr, oldcontents) << strerror(errno); oldbuf = (char*)malloc(oldsize); ASSERT_NE(nullptr, oldbuf) << strerror(errno); expect_lookup(RELPATH, ino, oldsize); expect_open(ino, 0, 1); expect_read(ino, 0, oldsize, oldsize, oldcontents); maybe_expect_write(ino, oldsize, BUFSIZE, CONTENTS); /* Must open O_RDWR or fuse(4) implicitly sets direct_io */ fd = open(FULLPATH, O_RDWR | O_APPEND); ASSERT_LE(0, fd) << strerror(errno); /* Read the old data into the cache */ ASSERT_EQ((ssize_t)oldsize, read(fd, oldbuf, oldsize)) << strerror(errno); /* Write the new data. There should be no more read operations */ ASSERT_EQ(BUFSIZE, write(fd, CONTENTS, BUFSIZE)) << strerror(errno); leak(fd); free(oldbuf); free(oldcontents); } TEST_F(Write, append_direct_io) { const ssize_t BUFSIZE = 9; const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char CONTENTS[BUFSIZE] = "abcdefgh"; uint64_t ino = 42; uint64_t initial_offset = 4096; int fd; expect_lookup(RELPATH, ino, initial_offset); expect_open(ino, FOPEN_DIRECT_IO, 1); expect_write(ino, initial_offset, BUFSIZE, BUFSIZE, CONTENTS); fd = open(FULLPATH, O_WRONLY | O_APPEND); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(BUFSIZE, write(fd, CONTENTS, BUFSIZE)) << strerror(errno); leak(fd); } /* A direct write should evict any overlapping cached data */ TEST_F(Write, direct_io_evicts_cache) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char CONTENTS0[] = "abcdefgh"; const char CONTENTS1[] = "ijklmnop"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS0) + 1; char readbuf[bufsize]; expect_lookup(RELPATH, ino, bufsize); expect_open(ino, 0, 1); expect_read(ino, 0, bufsize, bufsize, CONTENTS0); expect_write(ino, 0, bufsize, bufsize, CONTENTS1); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); // Prime cache ASSERT_EQ(bufsize, read(fd, readbuf, bufsize)) << strerror(errno); // Write directly, evicting cache ASSERT_EQ(0, fcntl(fd, F_SETFL, O_DIRECT)) << strerror(errno); ASSERT_EQ(0, lseek(fd, 0, SEEK_SET)) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS1, bufsize)) << strerror(errno); // Read again. Cache should be bypassed expect_read(ino, 0, bufsize, bufsize, CONTENTS1); ASSERT_EQ(0, fcntl(fd, F_SETFL, 0)) << strerror(errno); ASSERT_EQ(0, lseek(fd, 0, SEEK_SET)) << strerror(errno); ASSERT_EQ(bufsize, read(fd, readbuf, bufsize)) << strerror(errno); ASSERT_STREQ(readbuf, CONTENTS1); leak(fd); } /* * If the server doesn't return FOPEN_DIRECT_IO during FUSE_OPEN, then it's not * allowed to return a short write for that file handle. However, if it does * then we should still do our darndest to handle it by resending the unwritten * portion. */ TEST_F(Write, indirect_io_short_write) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefghijklmnop"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); ssize_t bufsize0 = 11; ssize_t bufsize1 = strlen(CONTENTS) - bufsize0; const char *contents1 = CONTENTS + bufsize0; expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); expect_write(ino, 0, bufsize, bufsize0, CONTENTS); expect_write(ino, bufsize0, bufsize1, bufsize1, contents1); fd = open(FULLPATH, O_WRONLY); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); leak(fd); } /* It is an error if the daemon claims to have written more data than we sent */ TEST_F(Write, indirect_io_long_write) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefghijklmnop"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); ssize_t bufsize_out = 100; off_t some_other_size = 25; struct stat sb; expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); expect_write(ino, 0, bufsize, bufsize_out, CONTENTS); expect_getattr(ino, some_other_size); fd = open(FULLPATH, O_WRONLY); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(-1, write(fd, CONTENTS, bufsize)) << strerror(errno); ASSERT_EQ(EINVAL, errno); /* * Following such an error, we should requery the server for the file's * size. */ fstat(fd, &sb); ASSERT_EQ(sb.st_size, some_other_size); leak(fd); } /* * Don't crash if the server returns a write that can't be represented as a * signed 32 bit number. Regression test for * https://bugs.freebsd.org/bugzilla/show_bug.cgi?id=263263 */ TEST_F(Write, indirect_io_very_long_write) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefghijklmnop"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); ssize_t bufsize_out = 3 << 30; expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); expect_write(ino, 0, bufsize, bufsize_out, CONTENTS); fd = open(FULLPATH, O_WRONLY); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(-1, write(fd, CONTENTS, bufsize)) << strerror(errno); ASSERT_EQ(EINVAL, errno); leak(fd); } /* * When the direct_io option is used, filesystems are allowed to write less * data than requested. We should return the short write to userland. */ TEST_F(Write, direct_io_short_write) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefghijklmnop"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); ssize_t halfbufsize = bufsize / 2; expect_lookup(RELPATH, ino, 0); expect_open(ino, FOPEN_DIRECT_IO, 1); expect_write(ino, 0, bufsize, halfbufsize, CONTENTS); fd = open(FULLPATH, O_WRONLY); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(halfbufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); leak(fd); } /* * An insidious edge case: the filesystem returns a short write, and the * difference between what we requested and what it actually wrote crosses an * iov element boundary */ TEST_F(Write, direct_io_short_write_iov) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS0 = "abcdefgh"; const char *CONTENTS1 = "ijklmnop"; const char *EXPECTED0 = "abcdefghijklmnop"; uint64_t ino = 42; int fd; ssize_t size0 = strlen(CONTENTS0) - 1; ssize_t size1 = strlen(CONTENTS1) + 1; ssize_t totalsize = size0 + size1; struct iovec iov[2]; expect_lookup(RELPATH, ino, 0); expect_open(ino, FOPEN_DIRECT_IO, 1); expect_write(ino, 0, totalsize, size0, EXPECTED0); fd = open(FULLPATH, O_WRONLY); ASSERT_LE(0, fd) << strerror(errno); iov[0].iov_base = __DECONST(void*, CONTENTS0); iov[0].iov_len = strlen(CONTENTS0); iov[1].iov_base = __DECONST(void*, CONTENTS1); iov[1].iov_len = strlen(CONTENTS1); ASSERT_EQ(size0, writev(fd, iov, 2)) << strerror(errno); leak(fd); } /* fusefs should respect RLIMIT_FSIZE */ TEST_P(WriteRlimitFsize, rlimit_fsize) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; struct rlimit rl; ssize_t bufsize = strlen(CONTENTS); off_t offset = 1'000'000'000; uint64_t ino = 42; int fd, oflag; oflag = GetParam(); expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); rl.rlim_cur = offset; rl.rlim_max = m_initial_limit.rlim_max; ASSERT_EQ(0, setrlimit(RLIMIT_FSIZE, &rl)) << strerror(errno); ASSERT_NE(SIG_ERR, signal(SIGXFSZ, sigxfsz_handler)) << strerror(errno); fd = open(FULLPATH, O_WRONLY | oflag); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(-1, pwrite(fd, CONTENTS, bufsize, offset)); EXPECT_EQ(EFBIG, errno); EXPECT_EQ(1, s_sigxfsz); leak(fd); } /* * When crossing the RLIMIT_FSIZE boundary, writes should be truncated, not * aborted. * https://bugs.freebsd.org/bugzilla/show_bug.cgi?id=164793 */ TEST_P(WriteRlimitFsize, rlimit_fsize_truncate) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefghijklmnopqrstuvwxyz"; struct rlimit rl; ssize_t bufsize = strlen(CONTENTS); uint64_t ino = 42; off_t offset = 1 << 30; off_t limit = offset + strlen(CONTENTS) / 2; int fd, oflag; oflag = GetParam(); expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); expect_write(ino, offset, bufsize / 2, bufsize / 2, CONTENTS); rl.rlim_cur = limit; rl.rlim_max = m_initial_limit.rlim_max; ASSERT_EQ(0, setrlimit(RLIMIT_FSIZE, &rl)) << strerror(errno); ASSERT_NE(SIG_ERR, signal(SIGXFSZ, sigxfsz_handler)) << strerror(errno); fd = open(FULLPATH, O_WRONLY | oflag); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize / 2, pwrite(fd, CONTENTS, bufsize, offset)) << strerror(errno); leak(fd); } INSTANTIATE_TEST_CASE_P(W, WriteRlimitFsize, Values(0, O_DIRECT) ); /* * A short read indicates EOF. Test that nothing bad happens if we get EOF * during the R of a RMW operation. */ TEST_F(Write, eof_during_rmw) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; const char *INITIAL = "XXXXXXXXXX"; uint64_t ino = 42; uint64_t offset = 1; ssize_t bufsize = strlen(CONTENTS) + 1; off_t orig_fsize = 10; off_t truncated_fsize = 5; int fd; FuseTest::expect_lookup(RELPATH, ino, S_IFREG | 0644, orig_fsize, 1); expect_open(ino, 0, 1); expect_read(ino, 0, orig_fsize, truncated_fsize, INITIAL, O_RDWR); maybe_expect_write(ino, offset, bufsize, CONTENTS); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, pwrite(fd, CONTENTS, bufsize, offset)) << strerror(errno); leak(fd); } /* * VOP_STRATEGY should not query the server for the file's size, even if its * cached attributes have expired. * Regression test for https://bugs.freebsd.org/bugzilla/show_bug.cgi?id=256937 */ TEST_P(WriteEofDuringVnopStrategy, eof_during_vop_strategy) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; Sequence seq; const off_t filesize = 2 * m_maxbcachebuf; void *contents; uint64_t ino = 42; uint64_t attr_valid = 0; uint64_t attr_valid_nsec = 0; mode_t mode = S_IFREG | 0644; int fd; int ngetattrs; ngetattrs = GetParam(); contents = calloc(1, filesize); EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillRepeatedly(Invoke( ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = mode; out.body.entry.nodeid = ino; out.body.entry.attr.nlink = 1; out.body.entry.attr.size = filesize; out.body.entry.attr_valid = attr_valid; out.body.entry.attr_valid_nsec = attr_valid_nsec; }))); expect_open(ino, 0, 1); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_GETATTR && in.header.nodeid == ino); }, Eq(true)), _) ).Times(Between(ngetattrs - 1, ngetattrs)) .InSequence(seq) .WillRepeatedly(Invoke(ReturnImmediate([=](auto i __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; out.body.attr.attr.mode = mode; out.body.attr.attr_valid = attr_valid; out.body.attr.attr_valid_nsec = attr_valid_nsec; out.body.attr.attr.size = filesize; }))); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_GETATTR && in.header.nodeid == ino); }, Eq(true)), _) ).InSequence(seq) .WillRepeatedly(Invoke(ReturnImmediate([=](auto i __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; out.body.attr.attr.mode = mode; out.body.attr.attr_valid = attr_valid; out.body.attr.attr_valid_nsec = attr_valid_nsec; out.body.attr.attr.size = filesize / 2; }))); expect_write(ino, 0, filesize / 2, filesize / 2, contents); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(filesize / 2, write(fd, contents, filesize / 2)) << strerror(errno); } INSTANTIATE_TEST_CASE_P(W, WriteEofDuringVnopStrategy, Values(1, 2, 3) ); /* * If the kernel cannot be sure which uid, gid, or pid was responsible for a * write, then it must set the FUSE_WRITE_CACHE bit */ /* https://bugs.freebsd.org/bugzilla/show_bug.cgi?id=236378 */ TEST_F(Write, mmap) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); void *p; uint64_t offset = 10; size_t len; void *zeros, *expected; len = getpagesize(); zeros = calloc(1, len); ASSERT_NE(nullptr, zeros); expected = calloc(1, len); ASSERT_NE(nullptr, expected); memmove((uint8_t*)expected + offset, CONTENTS, bufsize); expect_lookup(RELPATH, ino, len); expect_open(ino, 0, 1); expect_read(ino, 0, len, len, zeros); /* * Writes from the pager may or may not be associated with the correct * pid, so they must set FUSE_WRITE_CACHE. */ FuseTest::expect_write(ino, 0, len, len, FUSE_WRITE_CACHE, 0, expected); expect_flush(ino, 1, ReturnErrno(0)); expect_release(ino, ReturnErrno(0)); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); p = mmap(NULL, len, PROT_READ | PROT_WRITE, MAP_SHARED, fd, 0); ASSERT_NE(MAP_FAILED, p) << strerror(errno); memmove((uint8_t*)p + offset, CONTENTS, bufsize); ASSERT_EQ(0, munmap(p, len)) << strerror(errno); close(fd); // Write mmap'd data on close free(expected); free(zeros); leak(fd); } TEST_F(Write, pwrite) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; uint64_t ino = 42; uint64_t offset = m_maxbcachebuf; int fd; ssize_t bufsize = strlen(CONTENTS); expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); expect_write(ino, offset, bufsize, bufsize, CONTENTS); fd = open(FULLPATH, O_WRONLY); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, pwrite(fd, CONTENTS, bufsize, offset)) << strerror(errno); leak(fd); } /* Writing a file should update its cached mtime and ctime */ TEST_F(Write, timestamps) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; ssize_t bufsize = strlen(CONTENTS); uint64_t ino = 42; struct stat sb0, sb1; int fd; expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); maybe_expect_write(ino, 0, bufsize, CONTENTS); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(0, fstat(fd, &sb0)) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); nap(); ASSERT_EQ(0, fstat(fd, &sb1)) << strerror(errno); EXPECT_EQ(sb0.st_atime, sb1.st_atime); EXPECT_NE(sb0.st_mtime, sb1.st_mtime); EXPECT_NE(sb0.st_ctime, sb1.st_ctime); leak(fd); } TEST_F(Write, write) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); expect_write(ino, 0, bufsize, bufsize, CONTENTS); fd = open(FULLPATH, O_WRONLY); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); leak(fd); } /* fuse(4) should not issue writes of greater size than the daemon requests */ TEST_F(WriteMaxWrite, write) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; int *contents; uint64_t ino = 42; int fd; ssize_t halfbufsize, bufsize; halfbufsize = m_mock->m_maxwrite; if (halfbufsize >= m_maxbcachebuf || halfbufsize >= m_maxphys) GTEST_SKIP() << "Must lower m_maxwrite for this test"; bufsize = halfbufsize * 2; contents = (int*)malloc(bufsize); ASSERT_NE(nullptr, contents); for (int i = 0; i < (int)bufsize / (int)sizeof(i); i++) { contents[i] = i; } expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); maybe_expect_write(ino, 0, halfbufsize, contents); maybe_expect_write(ino, halfbufsize, halfbufsize, &contents[halfbufsize / sizeof(int)]); fd = open(FULLPATH, O_WRONLY); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, contents, bufsize)) << strerror(errno); leak(fd); free(contents); } TEST_F(Write, write_nothing) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = ""; uint64_t ino = 42; int fd; ssize_t bufsize = 0; expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); fd = open(FULLPATH, O_WRONLY); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); leak(fd); } TEST_F(Write_7_8, write) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); expect_write_7_8(ino, 0, bufsize, bufsize, CONTENTS); fd = open(FULLPATH, O_WRONLY); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); leak(fd); } /* In writeback mode, dirty data should be written on close */ TEST_F(WriteBackAsync, close) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); expect_write(ino, 0, bufsize, bufsize, CONTENTS); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_SETATTR); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnImmediate([=](auto i __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; // Must match nodeid }))); expect_flush(ino, 1, ReturnErrno(0)); expect_release(ino, ReturnErrno(0)); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); close(fd); } /* In writeback mode, adjacent writes will be clustered together */ TEST_F(WriteCluster, clustering) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; uint64_t ino = 42; int i, fd; void *wbuf, *wbuf2x; ssize_t bufsize = m_maxbcachebuf; off_t filesize = 5 * bufsize; wbuf = malloc(bufsize); ASSERT_NE(nullptr, wbuf) << strerror(errno); memset(wbuf, 'X', bufsize); wbuf2x = malloc(2 * bufsize); ASSERT_NE(nullptr, wbuf2x) << strerror(errno); memset(wbuf2x, 'X', 2 * bufsize); expect_lookup(RELPATH, ino, filesize); expect_open(ino, 0, 1); /* * Writes of bufsize-bytes each should be clustered into greater sizes. * The amount of clustering is adaptive, so the first write actually * issued will be 2x bufsize and subsequent writes may be larger */ expect_write(ino, 0, 2 * bufsize, 2 * bufsize, wbuf2x); expect_write(ino, 2 * bufsize, 2 * bufsize, 2 * bufsize, wbuf2x); expect_flush(ino, 1, ReturnErrno(0)); expect_release(ino, ReturnErrno(0)); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); for (i = 0; i < 4; i++) { ASSERT_EQ(bufsize, write(fd, wbuf, bufsize)) << strerror(errno); } close(fd); free(wbuf2x); free(wbuf); } /* * When clustering writes, an I/O error to any of the cluster's children should * not panic the system on unmount */ /* * Regression test for bug 238585 * https://bugs.freebsd.org/bugzilla/show_bug.cgi?id=238565 */ TEST_F(WriteCluster, cluster_write_err) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; uint64_t ino = 42; int i, fd; void *wbuf; ssize_t bufsize = m_maxbcachebuf; off_t filesize = 4 * bufsize; wbuf = malloc(bufsize); ASSERT_NE(nullptr, wbuf) << strerror(errno); memset(wbuf, 'X', bufsize); expect_lookup(RELPATH, ino, filesize); expect_open(ino, 0, 1); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_WRITE); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnErrno(EIO))); expect_flush(ino, 1, ReturnErrno(0)); expect_release(ino, ReturnErrno(0)); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); for (i = 0; i < 3; i++) { ASSERT_EQ(bufsize, write(fd, wbuf, bufsize)) << strerror(errno); } close(fd); free(wbuf); } /* * In writeback mode, writes to an O_WRONLY file could trigger reads from the * server. The FUSE protocol explicitly allows that. */ TEST_F(WriteBack, rmw) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; const char *INITIAL = "XXXXXXXXXX"; uint64_t ino = 42; uint64_t offset = 1; off_t fsize = 10; int fd; ssize_t bufsize = strlen(CONTENTS); FuseTest::expect_lookup(RELPATH, ino, S_IFREG | 0644, fsize, 1); expect_open(ino, 0, 1); expect_read(ino, 0, fsize, fsize, INITIAL, O_WRONLY); maybe_expect_write(ino, offset, bufsize, CONTENTS); fd = open(FULLPATH, O_WRONLY); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, pwrite(fd, CONTENTS, bufsize, offset)) << strerror(errno); leak(fd); } /* * Without direct_io, writes should be committed to cache */ TEST_F(WriteBack, cache) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); uint8_t readbuf[bufsize]; expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); expect_write(ino, 0, bufsize, bufsize, CONTENTS); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); /* * A subsequent read should be serviced by cache, without querying the * filesystem daemon */ ASSERT_EQ(0, lseek(fd, 0, SEEK_SET)) << strerror(errno); ASSERT_EQ(bufsize, read(fd, readbuf, bufsize)) << strerror(errno); leak(fd); } /* * With O_DIRECT, writes should be not committed to cache. Admittedly this is * an odd test, because it would be unusual to use O_DIRECT for writes but not * reads. */ TEST_F(WriteBack, o_direct) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); uint8_t readbuf[bufsize]; expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); FuseTest::expect_write(ino, 0, bufsize, bufsize, 0, FUSE_WRITE_CACHE, CONTENTS); expect_read(ino, 0, bufsize, bufsize, CONTENTS); fd = open(FULLPATH, O_RDWR | O_DIRECT); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); /* A subsequent read must query the daemon because cache is empty */ ASSERT_EQ(0, lseek(fd, 0, SEEK_SET)) << strerror(errno); ASSERT_EQ(0, fcntl(fd, F_SETFL, 0)) << strerror(errno); ASSERT_EQ(bufsize, read(fd, readbuf, bufsize)) << strerror(errno); leak(fd); } TEST_F(WriteBack, direct_io) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); uint8_t readbuf[bufsize]; expect_lookup(RELPATH, ino, 0); expect_open(ino, FOPEN_DIRECT_IO, 1); FuseTest::expect_write(ino, 0, bufsize, bufsize, 0, FUSE_WRITE_CACHE, CONTENTS); expect_read(ino, 0, bufsize, bufsize, CONTENTS); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); /* A subsequent read must query the daemon because cache is empty */ ASSERT_EQ(0, lseek(fd, 0, SEEK_SET)) << strerror(errno); ASSERT_EQ(0, fcntl(fd, F_SETFL, 0)) << strerror(errno); ASSERT_EQ(bufsize, read(fd, readbuf, bufsize)) << strerror(errno); leak(fd); } /* * mmap should still be possible even if the server used direct_io. Mmap will * still use the cache, though. * * Regression test for bug 247276 * https://bugs.freebsd.org/bugzilla/show_bug.cgi?id=247276 */ TEST_F(WriteBack, mmap_direct_io) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; uint64_t ino = 42; int fd; size_t len; ssize_t bufsize = strlen(CONTENTS); void *p, *zeros; len = getpagesize(); zeros = calloc(1, len); ASSERT_NE(nullptr, zeros); expect_lookup(RELPATH, ino, len); expect_open(ino, FOPEN_DIRECT_IO, 1); expect_read(ino, 0, len, len, zeros); expect_flush(ino, 1, ReturnErrno(0)); FuseTest::expect_write(ino, 0, len, len, FUSE_WRITE_CACHE, 0, zeros); expect_release(ino, ReturnErrno(0)); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); p = mmap(NULL, len, PROT_READ | PROT_WRITE, MAP_SHARED, fd, 0); ASSERT_NE(MAP_FAILED, p) << strerror(errno); memmove((uint8_t*)p, CONTENTS, bufsize); ASSERT_EQ(0, munmap(p, len)) << strerror(errno); close(fd); // Write mmap'd data on close free(zeros); } /* * When mounted with -o async, the writeback cache mode should delay writes */ TEST_F(WriteBackAsync, delay) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); /* Write should be cached, but FUSE_WRITE shouldn't be sent */ EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_WRITE); }, Eq(true)), _) ).Times(0); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); /* Don't close the file because that would flush the cache */ leak(fd); } /* * A direct write should not evict dirty cached data from outside of its own * byte range. */ TEST_F(WriteBackAsync, direct_io_ignores_unrelated_cached) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char CONTENTS0[] = "abcdefgh"; const char CONTENTS1[] = "ijklmnop"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS0) + 1; ssize_t fsize = 2 * m_maxbcachebuf; char readbuf[bufsize]; void *zeros; zeros = calloc(1, m_maxbcachebuf); ASSERT_NE(nullptr, zeros); expect_lookup(RELPATH, ino, fsize); expect_open(ino, 0, 1); expect_read(ino, 0, m_maxbcachebuf, m_maxbcachebuf, zeros); FuseTest::expect_write(ino, m_maxbcachebuf, bufsize, bufsize, 0, 0, CONTENTS1); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); // Cache first block with dirty data. This will entail first reading // the existing data. ASSERT_EQ(bufsize, pwrite(fd, CONTENTS0, bufsize, 0)) << strerror(errno); // Write directly to second block ASSERT_EQ(0, fcntl(fd, F_SETFL, O_DIRECT)) << strerror(errno); ASSERT_EQ(bufsize, pwrite(fd, CONTENTS1, bufsize, m_maxbcachebuf)) << strerror(errno); // Read from the first block again. Should be serviced by cache. ASSERT_EQ(0, fcntl(fd, F_SETFL, 0)) << strerror(errno); ASSERT_EQ(bufsize, pread(fd, readbuf, bufsize, 0)) << strerror(errno); ASSERT_STREQ(readbuf, CONTENTS0); leak(fd); free(zeros); } /* * If a direct io write partially overlaps one or two blocks of dirty cached * data, No dirty data should be lost. Admittedly this is a weird test, * because it would be unusual to use O_DIRECT and the writeback cache. */ TEST_F(WriteBackAsync, direct_io_partially_overlaps_cached_block) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; uint64_t ino = 42; int fd; off_t bs = m_maxbcachebuf; ssize_t fsize = 3 * bs; void *readbuf, *zeros, *ones, *zeroones, *onezeros; readbuf = malloc(bs); ASSERT_NE(nullptr, readbuf) << strerror(errno); zeros = calloc(1, 3 * bs); ASSERT_NE(nullptr, zeros); ones = calloc(1, 2 * bs); ASSERT_NE(nullptr, ones); memset(ones, 1, 2 * bs); zeroones = calloc(1, bs); ASSERT_NE(nullptr, zeroones); memset((uint8_t*)zeroones + bs / 2, 1, bs / 2); onezeros = calloc(1, bs); ASSERT_NE(nullptr, onezeros); memset(onezeros, 1, bs / 2); expect_lookup(RELPATH, ino, fsize); expect_open(ino, 0, 1); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); /* Cache first and third blocks with dirty data. */ ASSERT_EQ(3 * bs, pwrite(fd, zeros, 3 * bs, 0)) << strerror(errno); /* * Write directly to all three blocks. The partially written blocks * will be flushed because they're dirty. */ FuseTest::expect_write(ino, 0, bs, bs, 0, 0, zeros); FuseTest::expect_write(ino, 2 * bs, bs, bs, 0, 0, zeros); /* The direct write is split in two because of the m_maxwrite value */ FuseTest::expect_write(ino, bs / 2, bs, bs, 0, 0, ones); FuseTest::expect_write(ino, 3 * bs / 2, bs, bs, 0, 0, ones); ASSERT_EQ(0, fcntl(fd, F_SETFL, O_DIRECT)) << strerror(errno); ASSERT_EQ(2 * bs, pwrite(fd, ones, 2 * bs, bs / 2)) << strerror(errno); /* * Read from both the valid and invalid portions of the first and third * blocks again. This will entail FUSE_READ operations because these * blocks were invalidated by the direct write. */ expect_read(ino, 0, bs, bs, zeroones); expect_read(ino, 2 * bs, bs, bs, onezeros); ASSERT_EQ(0, fcntl(fd, F_SETFL, 0)) << strerror(errno); ASSERT_EQ(bs / 2, pread(fd, readbuf, bs / 2, 0)) << strerror(errno); EXPECT_EQ(0, memcmp(zeros, readbuf, bs / 2)); ASSERT_EQ(bs / 2, pread(fd, readbuf, bs / 2, 5 * bs / 2)) << strerror(errno); EXPECT_EQ(0, memcmp(zeros, readbuf, bs / 2)); ASSERT_EQ(bs / 2, pread(fd, readbuf, bs / 2, bs / 2)) << strerror(errno); EXPECT_EQ(0, memcmp(ones, readbuf, bs / 2)); ASSERT_EQ(bs / 2, pread(fd, readbuf, bs / 2, 2 * bs)) << strerror(errno); EXPECT_EQ(0, memcmp(ones, readbuf, bs / 2)); leak(fd); free(zeroones); free(onezeros); free(ones); free(zeros); free(readbuf); } /* * In WriteBack mode, writes may be cached beyond what the server thinks is the * EOF. In this case, a short read at EOF should _not_ cause fusefs to update * the file's size. */ TEST_F(WriteBackAsync, eof) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS0 = "abcdefgh"; const char *CONTENTS1 = "ijklmnop"; uint64_t ino = 42; int fd; off_t offset = m_maxbcachebuf; ssize_t wbufsize = strlen(CONTENTS1); off_t old_filesize = (off_t)strlen(CONTENTS0); ssize_t rbufsize = 2 * old_filesize; char readbuf[rbufsize]; size_t holesize = rbufsize - old_filesize; char hole[holesize]; struct stat sb; ssize_t r; expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); expect_read(ino, 0, m_maxbcachebuf, old_filesize, CONTENTS0); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); /* Write and cache data beyond EOF */ ASSERT_EQ(wbufsize, pwrite(fd, CONTENTS1, wbufsize, offset)) << strerror(errno); /* Read from the old EOF */ r = pread(fd, readbuf, rbufsize, 0); ASSERT_LE(0, r) << strerror(errno); EXPECT_EQ(rbufsize, r) << "read should've synthesized a hole"; EXPECT_EQ(0, memcmp(CONTENTS0, readbuf, old_filesize)); bzero(hole, holesize); EXPECT_EQ(0, memcmp(hole, readbuf + old_filesize, holesize)); /* The file's size should still be what was established by pwrite */ ASSERT_EQ(0, fstat(fd, &sb)) << strerror(errno); EXPECT_EQ(offset + wbufsize, sb.st_size); leak(fd); } /* * When a file has dirty writes that haven't been flushed, the server's notion * of its mtime and ctime will be wrong. The kernel should ignore those if it * gets them from a FUSE_GETATTR before flushing. */ TEST_F(WriteBackAsync, timestamps) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; ssize_t bufsize = strlen(CONTENTS); uint64_t ino = 42; uint64_t attr_valid = 0; uint64_t attr_valid_nsec = 0; uint64_t server_time = 12345; mode_t mode = S_IFREG | 0644; int fd; struct stat sb; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillRepeatedly(Invoke( ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = mode; out.body.entry.nodeid = ino; out.body.entry.attr.nlink = 1; out.body.entry.attr_valid = attr_valid; out.body.entry.attr_valid_nsec = attr_valid_nsec; }))); expect_open(ino, 0, 1); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_GETATTR && in.header.nodeid == ino); }, Eq(true)), _) ).WillRepeatedly(Invoke( ReturnImmediate([=](auto i __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; out.body.attr.attr.mode = mode; out.body.attr.attr_valid = attr_valid; out.body.attr.attr_valid_nsec = attr_valid_nsec; out.body.attr.attr.atime = server_time; out.body.attr.attr.mtime = server_time; out.body.attr.attr.ctime = server_time; }))); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); ASSERT_EQ(0, fstat(fd, &sb)) << strerror(errno); EXPECT_EQ((time_t)server_time, sb.st_atime); EXPECT_NE((time_t)server_time, sb.st_mtime); EXPECT_NE((time_t)server_time, sb.st_ctime); leak(fd); } /* Any dirty timestamp fields should be flushed during a SETATTR */ TEST_F(WriteBackAsync, timestamps_during_setattr) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; ssize_t bufsize = strlen(CONTENTS); uint64_t ino = 42; const mode_t newmode = 0755; int fd; expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { uint32_t valid = FATTR_MODE | FATTR_MTIME | FATTR_CTIME; return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && in.body.setattr.valid == valid); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; out.body.attr.attr.mode = S_IFREG | newmode; }))); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); ASSERT_EQ(0, fchmod(fd, newmode)) << strerror(errno); leak(fd); } /* fuse_init_out.time_gran controls the granularity of timestamps */ TEST_P(TimeGran, timestamps_during_setattr) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; ssize_t bufsize = strlen(CONTENTS); uint64_t ino = 42; const mode_t newmode = 0755; int fd; expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { uint32_t valid = FATTR_MODE | FATTR_MTIME | FATTR_CTIME; return (in.header.opcode == FUSE_SETATTR && in.header.nodeid == ino && in.body.setattr.valid == valid && in.body.setattr.mtimensec % m_time_gran == 0 && in.body.setattr.ctimensec % m_time_gran == 0); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, attr); out.body.attr.attr.ino = ino; out.body.attr.attr.mode = S_IFREG | newmode; }))); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); ASSERT_EQ(0, fchmod(fd, newmode)) << strerror(errno); leak(fd); } INSTANTIATE_TEST_CASE_P(RA, TimeGran, Range(0u, 10u)); /* * Without direct_io, writes should be committed to cache */ TEST_F(Write, writethrough) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); uint8_t readbuf[bufsize]; expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); expect_write(ino, 0, bufsize, bufsize, CONTENTS); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); /* * A subsequent read should be serviced by cache, without querying the * filesystem daemon */ ASSERT_EQ(0, lseek(fd, 0, SEEK_SET)) << strerror(errno); ASSERT_EQ(bufsize, read(fd, readbuf, bufsize)) << strerror(errno); leak(fd); } /* Writes that extend a file should update the cached file size */ TEST_F(Write, update_file_size) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefgh"; struct stat sb; uint64_t ino = 42; int fd; ssize_t bufsize = strlen(CONTENTS); expect_lookup(RELPATH, ino, 0); expect_open(ino, 0, 1); expect_write(ino, 0, bufsize, bufsize, CONTENTS); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(bufsize, write(fd, CONTENTS, bufsize)) << strerror(errno); /* Get cached attributes */ ASSERT_EQ(0, fstat(fd, &sb)) << strerror(errno); ASSERT_EQ(bufsize, sb.st_size); leak(fd); }