// Copyright 2018 The gVisor Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include #include #include #include #include #include "absl/time/clock.h" #include "test/util/multiprocess_util.h" #include "test/util/posix_error.h" #include "test/util/temp_path.h" #include "test/util/test_util.h" namespace gvisor { namespace testing { namespace { using ::testing::_; using ::testing::AnyOf; using ::testing::Eq; const uint64_t kAllocSize = kPageSize * 128ULL; PosixErrorOr Shmat(int shmid, const void* shmaddr, int shmflg) { const intptr_t addr = reinterpret_cast(shmat(shmid, shmaddr, shmflg)); if (addr == -1) { return PosixError(errno, "shmat() failed"); } return reinterpret_cast(addr); } PosixError Shmdt(const char* shmaddr) { const int ret = shmdt(shmaddr); if (ret == -1) { return PosixError(errno, "shmdt() failed"); } return NoError(); } template PosixErrorOr Shmctl(int shmid, int cmd, T* buf) { int ret = shmctl(shmid, cmd, reinterpret_cast(buf)); if (ret == -1) { return PosixError(errno, "shmctl() failed"); } return ret; } // ShmSegment is a RAII object for automatically cleaning up shm segments. class ShmSegment { public: explicit ShmSegment(int id) : id_(id) {} ~ShmSegment() { if (id_ >= 0) { EXPECT_NO_ERRNO(Rmid()); id_ = -1; } } ShmSegment(ShmSegment&& other) : id_(other.release()) {} ShmSegment& operator=(ShmSegment&& other) { id_ = other.release(); return *this; } ShmSegment(ShmSegment const& other) = delete; ShmSegment& operator=(ShmSegment const& other) = delete; int id() const { return id_; } int release() { int id = id_; id_ = -1; return id; } PosixErrorOr Rmid() { RETURN_IF_ERRNO(Shmctl(id_, IPC_RMID, nullptr)); return release(); } private: int id_ = -1; }; PosixErrorOr ShmgetRaw(key_t key, size_t size, int shmflg) { int id = shmget(key, size, shmflg); if (id == -1) { return PosixError(errno, "shmget() failed"); } return id; } PosixErrorOr Shmget(key_t key, size_t size, int shmflg) { ASSIGN_OR_RETURN_ERRNO(int id, ShmgetRaw(key, size, shmflg)); return ShmSegment(id); } TEST(ShmTest, AttachDetach) { const ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE( Shmget(IPC_PRIVATE, kAllocSize, IPC_CREAT | 0777)); struct shmid_ds attr; ASSERT_NO_ERRNO(Shmctl(shm.id(), IPC_STAT, &attr)); EXPECT_EQ(attr.shm_segsz, kAllocSize); EXPECT_EQ(attr.shm_nattch, 0); const char* addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); ASSERT_NO_ERRNO(Shmctl(shm.id(), IPC_STAT, &attr)); EXPECT_EQ(attr.shm_nattch, 1); const char* addr2 = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); ASSERT_NO_ERRNO(Shmctl(shm.id(), IPC_STAT, &attr)); EXPECT_EQ(attr.shm_nattch, 2); ASSERT_NO_ERRNO(Shmdt(addr)); ASSERT_NO_ERRNO(Shmctl(shm.id(), IPC_STAT, &attr)); EXPECT_EQ(attr.shm_nattch, 1); ASSERT_NO_ERRNO(Shmdt(addr2)); ASSERT_NO_ERRNO(Shmctl(shm.id(), IPC_STAT, &attr)); EXPECT_EQ(attr.shm_nattch, 0); } TEST(ShmTest, LookupByKey) { const TempPath keyfile = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFile()); const key_t key = ftok(keyfile.path().c_str(), 1); const ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE(Shmget(key, kAllocSize, IPC_CREAT | 0777)); const int id2 = ASSERT_NO_ERRNO_AND_VALUE(ShmgetRaw(key, kAllocSize, 0777)); EXPECT_EQ(shm.id(), id2); } TEST(ShmTest, DetachedSegmentsPersist) { const ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE( Shmget(IPC_PRIVATE, kAllocSize, IPC_CREAT | 0777)); char* addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); addr[0] = 'x'; ASSERT_NO_ERRNO(Shmdt(addr)); // We should be able to re-attach to the same segment and get our data back. addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); EXPECT_EQ(addr[0], 'x'); ASSERT_NO_ERRNO(Shmdt(addr)); } TEST(ShmTest, MultipleDetachFails) { const ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE( Shmget(IPC_PRIVATE, kAllocSize, IPC_CREAT | 0777)); const char* addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); ASSERT_NO_ERRNO(Shmdt(addr)); EXPECT_THAT(Shmdt(addr), PosixErrorIs(EINVAL, _)); } TEST(ShmTest, IpcStat) { const TempPath keyfile = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFile()); const key_t key = ftok(keyfile.path().c_str(), 1); const time_t start = time(nullptr); const ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE(Shmget(key, kAllocSize, IPC_CREAT | 0777)); const uid_t uid = getuid(); const gid_t gid = getgid(); const pid_t pid = getpid(); struct shmid_ds attr; ASSERT_NO_ERRNO(Shmctl(shm.id(), IPC_STAT, &attr)); EXPECT_EQ(attr.shm_perm.__key, key); EXPECT_EQ(attr.shm_perm.uid, uid); EXPECT_EQ(attr.shm_perm.gid, gid); EXPECT_EQ(attr.shm_perm.cuid, uid); EXPECT_EQ(attr.shm_perm.cgid, gid); EXPECT_EQ(attr.shm_perm.mode, 0777); EXPECT_EQ(attr.shm_segsz, kAllocSize); EXPECT_EQ(attr.shm_atime, 0); EXPECT_EQ(attr.shm_dtime, 0); // Change time is set on creation. EXPECT_GE(attr.shm_ctime, start); EXPECT_EQ(attr.shm_cpid, pid); EXPECT_EQ(attr.shm_lpid, 0); EXPECT_EQ(attr.shm_nattch, 0); // The timestamps only have a resolution of seconds; slow down so we actually // see the timestamps change. absl::SleepFor(absl::Seconds(1)); const time_t pre_attach = time(nullptr); const char* addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); ASSERT_NO_ERRNO(Shmctl(shm.id(), IPC_STAT, &attr)); EXPECT_GE(attr.shm_atime, pre_attach); EXPECT_EQ(attr.shm_dtime, 0); EXPECT_LT(attr.shm_ctime, pre_attach); EXPECT_EQ(attr.shm_lpid, pid); EXPECT_EQ(attr.shm_nattch, 1); absl::SleepFor(absl::Seconds(1)); const time_t pre_detach = time(nullptr); ASSERT_NO_ERRNO(Shmdt(addr)); ASSERT_NO_ERRNO(Shmctl(shm.id(), IPC_STAT, &attr)); EXPECT_LT(attr.shm_atime, pre_detach); EXPECT_GE(attr.shm_dtime, pre_detach); EXPECT_LT(attr.shm_ctime, pre_detach); EXPECT_EQ(attr.shm_lpid, pid); EXPECT_EQ(attr.shm_nattch, 0); } TEST(ShmTest, ShmStat) { // This test relies on the segment we create to be the first one on the // system, causing it to occupy slot 1. We can't reasonably expect this on a // general Linux host. SKIP_IF(!IsRunningOnGvisor()); const ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE( Shmget(IPC_PRIVATE, kAllocSize, IPC_CREAT | 0777)); struct shmid_ds attr; ASSERT_NO_ERRNO(Shmctl(1, SHM_STAT, &attr)); // This does the same thing as IPC_STAT, so only test that the syscall // succeeds here. } TEST(ShmTest, IpcInfo) { struct shminfo info; ASSERT_NO_ERRNO(Shmctl(0, IPC_INFO, &info)); EXPECT_EQ(info.shmmin, 1); // This is always 1, according to the man page. EXPECT_GT(info.shmmax, info.shmmin); EXPECT_GT(info.shmmni, 0); EXPECT_GT(info.shmseg, 0); EXPECT_GT(info.shmall, 0); } TEST(ShmTest, ShmInfo) { // Take a snapshot of the system before the test runs. struct shm_info snap; ASSERT_NO_ERRNO(Shmctl(0, SHM_INFO, &snap)); const ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE( Shmget(IPC_PRIVATE, kAllocSize, IPC_CREAT | 0777)); const char* addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); struct shm_info info; ASSERT_NO_ERRNO(Shmctl(1, SHM_INFO, &info)); // We generally can't know what other processes on a linux machine do with // shared memory segments, so we can't test specific numbers on Linux. When // running under gvisor, we're guaranteed to be the only ones using shm, so // we can easily verify machine-wide numbers. if (IsRunningOnGvisor()) { ASSERT_NO_ERRNO(Shmctl(shm.id(), SHM_INFO, &info)); EXPECT_EQ(info.used_ids, snap.used_ids + 1); EXPECT_EQ(info.shm_tot, snap.shm_tot + (kAllocSize / kPageSize)); EXPECT_EQ(info.shm_rss, snap.shm_rss + (kAllocSize / kPageSize)); EXPECT_EQ(info.shm_swp, 0); // Gvisor currently never swaps. } ASSERT_NO_ERRNO(Shmdt(addr)); } TEST(ShmTest, ShmCtlSet) { const ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE( Shmget(IPC_PRIVATE, kAllocSize, IPC_CREAT | 0777)); const char* addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); struct shmid_ds attr; ASSERT_NO_ERRNO(Shmctl(shm.id(), IPC_STAT, &attr)); ASSERT_EQ(attr.shm_perm.mode, 0777); attr.shm_perm.mode = 0766; ASSERT_NO_ERRNO(Shmctl(shm.id(), IPC_SET, &attr)); ASSERT_NO_ERRNO(Shmctl(shm.id(), IPC_STAT, &attr)); ASSERT_EQ(attr.shm_perm.mode, 0766); ASSERT_NO_ERRNO(Shmdt(addr)); } TEST(ShmTest, RemovedSegmentsAreMarkedDeleted) { ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE( Shmget(IPC_PRIVATE, kAllocSize, IPC_CREAT | 0777)); const char* addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); const int id = ASSERT_NO_ERRNO_AND_VALUE(shm.Rmid()); struct shmid_ds attr; ASSERT_NO_ERRNO(Shmctl(id, IPC_STAT, &attr)); EXPECT_NE(attr.shm_perm.mode & SHM_DEST, 0); ASSERT_NO_ERRNO(Shmdt(addr)); } TEST(ShmTest, RemovedSegmentsAreDestroyed) { ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE( Shmget(IPC_PRIVATE, kAllocSize, IPC_CREAT | 0777)); const char* addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); const uint64_t alloc_pages = kAllocSize / kPageSize; struct shm_info info; ASSERT_NO_ERRNO(Shmctl(0 /*ignored*/, SHM_INFO, &info)); const uint64_t before = info.shm_tot; ASSERT_NO_ERRNO(shm.Rmid()); ASSERT_NO_ERRNO(Shmdt(addr)); ASSERT_NO_ERRNO(Shmctl(0 /*ignored*/, SHM_INFO, &info)); if (IsRunningOnGvisor()) { // No guarantees on system-wide shm memory usage on a generic linux host. const uint64_t after = info.shm_tot; EXPECT_EQ(after, before - alloc_pages); } } TEST(ShmTest, AllowsAttachToRemovedSegmentWithRefs) { ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE( Shmget(IPC_PRIVATE, kAllocSize, IPC_CREAT | 0777)); const char* addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); const int id = ASSERT_NO_ERRNO_AND_VALUE(shm.Rmid()); const char* addr2 = ASSERT_NO_ERRNO_AND_VALUE(Shmat(id, nullptr, 0)); ASSERT_NO_ERRNO(Shmdt(addr)); ASSERT_NO_ERRNO(Shmdt(addr2)); } TEST(ShmTest, RemovedSegmentsAreNotDiscoverable) { const TempPath keyfile = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFile()); const key_t key = ftok(keyfile.path().c_str(), 1); ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE(Shmget(key, kAllocSize, IPC_CREAT | 0777)); ASSERT_NO_ERRNO(shm.Rmid()); EXPECT_THAT(Shmget(key, kAllocSize, 0777), PosixErrorIs(ENOENT, _)); } TEST(ShmDeathTest, ReadonlySegment) { SetupGvisorDeathTest(); const ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE( Shmget(IPC_PRIVATE, kAllocSize, IPC_CREAT | 0777)); char* addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, SHM_RDONLY)); // Reading succeeds. static_cast(addr[0]); // Writing fails. EXPECT_EXIT(addr[0] = 'x', ::testing::KilledBySignal(SIGSEGV), ""); } TEST(ShmDeathTest, SegmentNotAccessibleAfterDetach) { // This test is susceptible to races with concurrent mmaps running in parallel // gtest threads since the test relies on the address freed during a shm // segment destruction to remain unused. We run the test body in a forked // child to guarantee a single-threaded context to avoid this. SetupGvisorDeathTest(); const auto rest = [&] { ShmSegment shm = TEST_CHECK_NO_ERRNO_AND_VALUE( Shmget(IPC_PRIVATE, kAllocSize, IPC_CREAT | 0777)); char* addr = TEST_CHECK_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); // Mark the segment as destroyed so it's automatically cleaned up when we // crash below. We can't rely on the standard cleanup since the destructor // will not run after the SIGSEGV. Note that this doesn't destroy the // segment immediately since we're still attached to it. TEST_CHECK_NO_ERRNO(shm.Rmid()); addr[0] = 'x'; TEST_CHECK_NO_ERRNO(Shmdt(addr)); // This access should cause a SIGSEGV. addr[0] = 'x'; }; EXPECT_THAT(InForkedProcess(rest), IsPosixErrorOkAndHolds(AnyOf(Eq(W_EXITCODE(0, SIGSEGV)), Eq(W_EXITCODE(0, 128 + SIGSEGV))))); } TEST(ShmTest, RequestingSegmentSmallerThanSHMMINFails) { struct shminfo info; ASSERT_NO_ERRNO(Shmctl(0, IPC_INFO, &info)); const uint64_t size = info.shmmin - 1; EXPECT_THAT(Shmget(IPC_PRIVATE, size, IPC_CREAT | 0777), PosixErrorIs(EINVAL, _)); } TEST(ShmTest, RequestingSegmentLargerThanSHMMAXFails) { struct shminfo info; ASSERT_NO_ERRNO(Shmctl(0, IPC_INFO, &info)); const uint64_t size = info.shmmax + kPageSize; EXPECT_THAT(Shmget(IPC_PRIVATE, size, IPC_CREAT | 0777), PosixErrorIs(EINVAL, _)); } TEST(ShmTest, RequestingUnalignedSizeSucceeds) { EXPECT_NO_ERRNO(Shmget(IPC_PRIVATE, 4097, IPC_CREAT | 0777)); } TEST(ShmTest, RequestingDuplicateCreationFails) { const TempPath keyfile = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFile()); const key_t key = ftok(keyfile.path().c_str(), 1); const ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE( Shmget(key, kAllocSize, IPC_CREAT | IPC_EXCL | 0777)); EXPECT_THAT(Shmget(key, kAllocSize, IPC_CREAT | IPC_EXCL | 0777), PosixErrorIs(EEXIST, _)); } TEST(ShmTest, NonExistentSegmentsAreNotFound) { const TempPath keyfile = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFile()); const key_t key = ftok(keyfile.path().c_str(), 1); // Do not request creation. EXPECT_THAT(Shmget(key, kAllocSize, 0777), PosixErrorIs(ENOENT, _)); } TEST(ShmTest, SegmentsSizeFixedOnCreation) { const TempPath keyfile = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFile()); const key_t key = ftok(keyfile.path().c_str(), 1); // Base segment. const ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE(Shmget(key, kAllocSize, IPC_CREAT | 0777)); // Ask for the same segment at half size. This succeeds. const int id2 = ASSERT_NO_ERRNO_AND_VALUE(ShmgetRaw(key, kAllocSize / 2, 0777)); // Ask for the same segment at double size. EXPECT_THAT(Shmget(key, kAllocSize * 2, 0777), PosixErrorIs(EINVAL, _)); char* addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); char* addr2 = ASSERT_NO_ERRNO_AND_VALUE(Shmat(id2, nullptr, 0)); // We have 2 different maps... EXPECT_NE(addr, addr2); // ... And both maps are kAllocSize bytes; despite asking for a half-sized // segment for the second map. addr[kAllocSize - 1] = 'x'; addr2[kAllocSize - 1] = 'x'; ASSERT_NO_ERRNO(Shmdt(addr)); ASSERT_NO_ERRNO(Shmdt(addr2)); } TEST(ShmTest, PartialUnmap) { const ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE( Shmget(IPC_PRIVATE, kAllocSize, IPC_CREAT | 0777)); char* addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); EXPECT_THAT(munmap(addr + (kAllocSize / 4), kAllocSize / 2), SyscallSucceeds()); ASSERT_NO_ERRNO(Shmdt(addr)); } // Check that sentry does not panic when asked for a zero-length private shm // segment. Regression test for b/110694797. TEST(ShmTest, GracefullyFailOnZeroLenSegmentCreation) { EXPECT_THAT(Shmget(IPC_PRIVATE, 0, 0), PosixErrorIs(EINVAL, _)); } TEST(ShmTest, NoDestructionOfAttachedSegmentWithMultipleRmid) { ShmSegment shm = ASSERT_NO_ERRNO_AND_VALUE( Shmget(IPC_PRIVATE, kAllocSize, IPC_CREAT | 0777)); char* addr = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); char* addr2 = ASSERT_NO_ERRNO_AND_VALUE(Shmat(shm.id(), nullptr, 0)); // There should be 2 refs to the segment from the 2 attachments, and a single // self-reference. Mark the segment as destroyed more than 3 times through // shmctl(RMID). If there's a bug with the ref counting, this should cause the // count to drop to zero. int id = shm.release(); for (int i = 0; i < 6; ++i) { ASSERT_NO_ERRNO(Shmctl(id, IPC_RMID, nullptr)); } // Segment should remain accessible. addr[0] = 'x'; ASSERT_NO_ERRNO(Shmdt(addr)); // Segment should remain accessible even after one of the two attachments are // detached. addr2[0] = 'x'; ASSERT_NO_ERRNO(Shmdt(addr2)); } } // namespace } // namespace testing } // namespace gvisor