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|
// Copyright 2018 Google LLC
//
// 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 <elf.h>
#include <errno.h>
#include <fcntl.h>
#include <limits.h>
#include <sched.h>
#include <signal.h>
#include <stddef.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/mman.h>
#include <sys/prctl.h>
#include <sys/stat.h>
#include <sys/utsname.h>
#include <syscall.h>
#include <unistd.h>
#include <algorithm>
#include <atomic>
#include <functional>
#include <map>
#include <memory>
#include <string>
#include <utility>
#include <vector>
#include "gmock/gmock.h"
#include "gtest/gtest.h"
#include "absl/strings/ascii.h"
#include "absl/strings/match.h"
#include "absl/strings/numbers.h"
#include "absl/strings/str_cat.h"
#include "absl/strings/str_split.h"
#include "absl/strings/string_view.h"
#include "absl/synchronization/mutex.h"
#include "absl/time/clock.h"
#include "absl/time/time.h"
#include "test/util/capability_util.h"
#include "test/util/cleanup.h"
#include "test/util/file_descriptor.h"
#include "test/util/fs_util.h"
#include "test/util/memory_util.h"
#include "test/util/posix_error.h"
#include "test/util/temp_path.h"
#include "test/util/test_util.h"
#include "test/util/thread_util.h"
#include "test/util/timer_util.h"
// NOTE: No, this isn't really a syscall but this is a really simple
// way to get it tested on both gVisor, PTrace and Linux.
using ::testing::AllOf;
using ::testing::ContainerEq;
using ::testing::Contains;
using ::testing::ContainsRegex;
using ::testing::Gt;
using ::testing::HasSubstr;
using ::testing::IsSupersetOf;
using ::testing::Pair;
using ::testing::UnorderedElementsAre;
using ::testing::UnorderedElementsAreArray;
// Exported by glibc.
extern char** environ;
namespace gvisor {
namespace testing {
namespace {
// O_LARGEFILE as defined by Linux. glibc tries to be clever by setting it to 0
// because "it isn't needed", even though Linux can return it via F_GETFL.
constexpr int kOLargeFile = 00100000;
// Takes the subprocess command line and pid.
// If it returns !OK, WithSubprocess returns immediately.
using SubprocessCallback = std::function<PosixError(int)>;
std::vector<std::string> saved_argv; // NOLINT
// Helper function to dump /proc/{pid}/status and check the
// state data. State should = "Z" for zombied or "RSD" for
// running, interruptible sleeping (S), or uninterruptible sleep
// (D).
void CompareProcessState(absl::string_view state, int pid) {
auto status_file = ASSERT_NO_ERRNO_AND_VALUE(
GetContents(absl::StrCat("/proc/", pid, "/status")));
// N.B. POSIX extended regexes don't support shorthand character classes (\w)
// inside of brackets.
EXPECT_THAT(status_file,
ContainsRegex(absl::StrCat("State:.[", state,
R"EOL(]\s+\([a-zA-Z ]+\))EOL")));
}
// Run callbacks while a subprocess is running, zombied, and/or exited.
PosixError WithSubprocess(SubprocessCallback const& running,
SubprocessCallback const& zombied,
SubprocessCallback const& exited) {
int pipe_fds[2] = {};
if (pipe(pipe_fds) < 0) {
return PosixError(errno, "pipe");
}
int child_pid = fork();
if (child_pid < 0) {
return PosixError(errno, "fork");
}
if (child_pid == 0) {
close(pipe_fds[0]); // Close the read end.
const DisableSave ds; // Timing issues.
// Write to the pipe to tell it we're ready.
char buf = 'a';
int res = 0;
res = WriteFd(pipe_fds[1], &buf, sizeof(buf));
TEST_CHECK_MSG(res == sizeof(buf), "Write failure in subprocess");
while (true) {
SleepSafe(absl::Milliseconds(100));
}
__builtin_unreachable();
}
close(pipe_fds[1]); // Close the write end.
int status = 0;
auto wait_cleanup = Cleanup([child_pid, &status] {
EXPECT_THAT(waitpid(child_pid, &status, 0), SyscallSucceeds());
});
auto kill_cleanup = Cleanup([child_pid] {
EXPECT_THAT(kill(child_pid, SIGKILL), SyscallSucceeds());
});
// Wait for the child.
char buf = 0;
int res = ReadFd(pipe_fds[0], &buf, sizeof(buf));
if (res < 0) {
return PosixError(errno, "Read from pipe");
} else if (res == 0) {
return PosixError(EPIPE, "Unable to read from pipe: EOF");
}
if (running) {
// The first arg, RSD, refers to a "running process", or a process with a
// state of Running (R), Interruptable Sleep (S) or Uninterruptable
// Sleep (D).
CompareProcessState("RSD", child_pid);
RETURN_IF_ERRNO(running(child_pid));
}
// Kill the process.
kill_cleanup.Release()();
siginfo_t info;
// Wait until the child process has exited (WEXITED flag) but don't
// reap the child (WNOWAIT flag).
waitid(P_PID, child_pid, &info, WNOWAIT | WEXITED);
if (zombied) {
// Arg of "Z" refers to a Zombied Process.
CompareProcessState("Z", child_pid);
RETURN_IF_ERRNO(zombied(child_pid));
}
// Wait on the process.
wait_cleanup.Release()();
// If the process is reaped, then then this should return
// with ECHILD.
EXPECT_THAT(waitpid(child_pid, &status, WNOHANG),
SyscallFailsWithErrno(ECHILD));
if (exited) {
RETURN_IF_ERRNO(exited(child_pid));
}
return NoError();
}
// Access the file returned by name when a subprocess is running.
PosixError AccessWhileRunning(std::function<std::string(int pid)> name, int flags,
std::function<void(int fd)> access) {
FileDescriptor fd;
return WithSubprocess(
[&](int pid) -> PosixError {
// Running.
ASSIGN_OR_RETURN_ERRNO(fd, Open(name(pid), flags));
access(fd.get());
return NoError();
},
nullptr, nullptr);
}
// Access the file returned by name when the a subprocess is zombied.
PosixError AccessWhileZombied(std::function<std::string(int pid)> name, int flags,
std::function<void(int fd)> access) {
FileDescriptor fd;
return WithSubprocess(
[&](int pid) -> PosixError {
// Running.
ASSIGN_OR_RETURN_ERRNO(fd, Open(name(pid), flags));
return NoError();
},
[&](int pid) -> PosixError {
// Zombied.
access(fd.get());
return NoError();
},
nullptr);
}
// Access the file returned by name when the a subprocess is exited.
PosixError AccessWhileExited(std::function<std::string(int pid)> name, int flags,
std::function<void(int fd)> access) {
FileDescriptor fd;
return WithSubprocess(
[&](int pid) -> PosixError {
// Running.
ASSIGN_OR_RETURN_ERRNO(fd, Open(name(pid), flags));
return NoError();
},
nullptr,
[&](int pid) -> PosixError {
// Exited.
access(fd.get());
return NoError();
});
}
// ReadFd(fd=/proc/PID/basename) while PID is running.
int ReadWhileRunning(std::string const& basename, void* buf, size_t count) {
int ret = 0;
int err = 0;
EXPECT_NO_ERRNO(AccessWhileRunning(
[&](int pid) -> std::string {
return absl::StrCat("/proc/", pid, "/", basename);
},
O_RDONLY,
[&](int fd) {
ret = ReadFd(fd, buf, count);
err = errno;
}));
errno = err;
return ret;
}
// ReadFd(fd=/proc/PID/basename) while PID is zombied.
int ReadWhileZombied(std::string const& basename, void* buf, size_t count) {
int ret = 0;
int err = 0;
EXPECT_NO_ERRNO(AccessWhileZombied(
[&](int pid) -> std::string {
return absl::StrCat("/proc/", pid, "/", basename);
},
O_RDONLY,
[&](int fd) {
ret = ReadFd(fd, buf, count);
err = errno;
}));
errno = err;
return ret;
}
// ReadFd(fd=/proc/PID/basename) while PID is exited.
int ReadWhileExited(std::string const& basename, void* buf, size_t count) {
int ret = 0;
int err = 0;
EXPECT_NO_ERRNO(AccessWhileExited(
[&](int pid) -> std::string {
return absl::StrCat("/proc/", pid, "/", basename);
},
O_RDONLY,
[&](int fd) {
ret = ReadFd(fd, buf, count);
err = errno;
}));
errno = err;
return ret;
}
// readlinkat(fd=/proc/PID/, basename) while PID is running.
int ReadlinkWhileRunning(std::string const& basename, char* buf, size_t count) {
int ret = 0;
int err = 0;
EXPECT_NO_ERRNO(AccessWhileRunning(
[&](int pid) -> std::string { return absl::StrCat("/proc/", pid, "/"); },
O_DIRECTORY,
[&](int fd) {
ret = readlinkat(fd, basename.c_str(), buf, count);
err = errno;
}));
errno = err;
return ret;
}
// readlinkat(fd=/proc/PID/, basename) while PID is zombied.
int ReadlinkWhileZombied(std::string const& basename, char* buf, size_t count) {
int ret = 0;
int err = 0;
EXPECT_NO_ERRNO(AccessWhileZombied(
[&](int pid) -> std::string { return absl::StrCat("/proc/", pid, "/"); },
O_DIRECTORY,
[&](int fd) {
ret = readlinkat(fd, basename.c_str(), buf, count);
err = errno;
}));
errno = err;
return ret;
}
// readlinkat(fd=/proc/PID/, basename) while PID is exited.
int ReadlinkWhileExited(std::string const& basename, char* buf, size_t count) {
int ret = 0;
int err = 0;
EXPECT_NO_ERRNO(AccessWhileExited(
[&](int pid) -> std::string { return absl::StrCat("/proc/", pid, "/"); },
O_DIRECTORY,
[&](int fd) {
ret = readlinkat(fd, basename.c_str(), buf, count);
err = errno;
}));
errno = err;
return ret;
}
TEST(ProcTest, NotFoundInRoot) {
struct stat s;
EXPECT_THAT(stat("/proc/foobar", &s), SyscallFailsWithErrno(ENOENT));
}
TEST(ProcSelfTest, IsThreadGroupLeader) {
ScopedThread([] {
const pid_t tgid = getpid();
const pid_t tid = syscall(SYS_gettid);
EXPECT_NE(tgid, tid);
auto link = ASSERT_NO_ERRNO_AND_VALUE(ReadLink("/proc/self"));
EXPECT_EQ(link, absl::StrCat(tgid));
});
}
TEST(ProcThreadSelfTest, Basic) {
const pid_t tgid = getpid();
const pid_t tid = syscall(SYS_gettid);
EXPECT_EQ(tgid, tid);
auto link_threadself =
ASSERT_NO_ERRNO_AND_VALUE(ReadLink("/proc/thread-self"));
EXPECT_EQ(link_threadself, absl::StrCat(tgid, "/task/", tid));
// Just read one file inside thread-self to ensure that the link is valid.
auto link_threadself_exe =
ASSERT_NO_ERRNO_AND_VALUE(ReadLink("/proc/thread-self/exe"));
auto link_procself_exe =
ASSERT_NO_ERRNO_AND_VALUE(ReadLink("/proc/self/exe"));
EXPECT_EQ(link_threadself_exe, link_procself_exe);
}
TEST(ProcThreadSelfTest, Thread) {
ScopedThread([] {
const pid_t tgid = getpid();
const pid_t tid = syscall(SYS_gettid);
EXPECT_NE(tgid, tid);
auto link_threadself =
ASSERT_NO_ERRNO_AND_VALUE(ReadLink("/proc/thread-self"));
EXPECT_EQ(link_threadself, absl::StrCat(tgid, "/task/", tid));
// Just read one file inside thread-self to ensure that the link is valid.
auto link_threadself_exe =
ASSERT_NO_ERRNO_AND_VALUE(ReadLink("/proc/thread-self/exe"));
auto link_procself_exe =
ASSERT_NO_ERRNO_AND_VALUE(ReadLink("/proc/self/exe"));
EXPECT_EQ(link_threadself_exe, link_procself_exe);
// A thread should not have "/proc/<tid>/task".
struct stat s;
EXPECT_THAT(stat("/proc/thread-self/task", &s),
SyscallFailsWithErrno(ENOENT));
});
}
// Returns the /proc/PID/maps entry for the MAP_PRIVATE | MAP_ANONYMOUS mapping
// m with start address addr and length len.
std::string AnonymousMapsEntry(uintptr_t addr, size_t len, int prot) {
return absl::StrCat(absl::Hex(addr, absl::PadSpec::kZeroPad8), "-",
absl::Hex(addr + len, absl::PadSpec::kZeroPad8), " ",
prot & PROT_READ ? "r" : "-",
prot & PROT_WRITE ? "w" : "-",
prot & PROT_EXEC ? "x" : "-", "p 00000000 00:00 0 ");
}
std::string AnonymousMapsEntryForMapping(const Mapping& m, int prot) {
return AnonymousMapsEntry(m.addr(), m.len(), prot);
}
PosixErrorOr<std::map<uint64_t, uint64_t>> ReadProcSelfAuxv() {
std::string auxv_file;
RETURN_IF_ERRNO(GetContents("/proc/self/auxv", &auxv_file));
const Elf64_auxv_t* auxv_data =
reinterpret_cast<const Elf64_auxv_t*>(auxv_file.data());
std::map<uint64_t, uint64_t> auxv_entries;
for (int i = 0; auxv_data[i].a_type != AT_NULL; i++) {
auto a_type = auxv_data[i].a_type;
EXPECT_EQ(0, auxv_entries.count(a_type)) << "a_type: " << a_type;
auxv_entries.emplace(a_type, auxv_data[i].a_un.a_val);
}
return auxv_entries;
}
TEST(ProcSelfAuxv, EntryPresence) {
auto auxv_entries = ASSERT_NO_ERRNO_AND_VALUE(ReadProcSelfAuxv());
EXPECT_EQ(auxv_entries.count(AT_ENTRY), 1);
EXPECT_EQ(auxv_entries.count(AT_PHDR), 1);
EXPECT_EQ(auxv_entries.count(AT_PHENT), 1);
EXPECT_EQ(auxv_entries.count(AT_PHNUM), 1);
EXPECT_EQ(auxv_entries.count(AT_BASE), 1);
EXPECT_EQ(auxv_entries.count(AT_CLKTCK), 1);
EXPECT_EQ(auxv_entries.count(AT_RANDOM), 1);
EXPECT_EQ(auxv_entries.count(AT_EXECFN), 1);
EXPECT_EQ(auxv_entries.count(AT_PAGESZ), 1);
EXPECT_EQ(auxv_entries.count(AT_SYSINFO_EHDR), 1);
}
TEST(ProcSelfAuxv, EntryValues) {
auto proc_auxv = ASSERT_NO_ERRNO_AND_VALUE(ReadProcSelfAuxv());
// We need to find the ELF auxiliary vector. The section of memory pointed to
// by envp contains some pointers to non-null pointers, followed by a single
// pointer to a null pointer, followed by the auxiliary vector.
char** envpi = environ;
while (*envpi) {
++envpi;
}
const Elf64_auxv_t* envp_auxv =
reinterpret_cast<const Elf64_auxv_t*>(envpi + 1);
int i;
for (i = 0; envp_auxv[i].a_type != AT_NULL; i++) {
auto a_type = envp_auxv[i].a_type;
EXPECT_EQ(proc_auxv.count(a_type), 1);
EXPECT_EQ(proc_auxv[a_type], envp_auxv[i].a_un.a_val)
<< "a_type: " << a_type;
}
EXPECT_EQ(i, proc_auxv.size());
}
// Just open and read /proc/self/maps, check that we can find [stack]
TEST(ProcSelfMaps, Basic) {
auto proc_self_maps =
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/maps"));
std::vector<std::string> strings = absl::StrSplit(proc_self_maps, '\n');
std::vector<std::string> stacks;
// Make sure there's a stack in there.
for (const auto& str : strings) {
if (str.find("[stack]") != std::string::npos) {
stacks.push_back(str);
}
}
ASSERT_EQ(1, stacks.size()) << "[stack] not found in: " << proc_self_maps;
// Linux pads to 73 characters then we add 7.
EXPECT_EQ(80, stacks[0].length());
}
TEST(ProcSelfMaps, Map1) {
Mapping mapping =
ASSERT_NO_ERRNO_AND_VALUE(MmapAnon(kPageSize, PROT_READ, MAP_PRIVATE));
auto proc_self_maps =
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/maps"));
std::vector<std::string> strings = absl::StrSplit(proc_self_maps, '\n');
std::vector<std::string> addrs;
// Make sure if is listed.
for (const auto& str : strings) {
if (str == AnonymousMapsEntryForMapping(mapping, PROT_READ)) {
addrs.push_back(str);
}
}
ASSERT_EQ(1, addrs.size());
}
TEST(ProcSelfMaps, Map2) {
// NOTE: The permissions must be different or the pages will get merged.
Mapping map1 = ASSERT_NO_ERRNO_AND_VALUE(
MmapAnon(kPageSize, PROT_READ | PROT_EXEC, MAP_PRIVATE));
Mapping map2 =
ASSERT_NO_ERRNO_AND_VALUE(MmapAnon(kPageSize, PROT_WRITE, MAP_PRIVATE));
auto proc_self_maps =
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/maps"));
std::vector<std::string> strings = absl::StrSplit(proc_self_maps, '\n');
std::vector<std::string> addrs;
// Make sure if is listed.
for (const auto& str : strings) {
if (str == AnonymousMapsEntryForMapping(map1, PROT_READ | PROT_EXEC)) {
addrs.push_back(str);
}
}
ASSERT_EQ(1, addrs.size());
addrs.clear();
for (const auto& str : strings) {
if (str == AnonymousMapsEntryForMapping(map2, PROT_WRITE)) {
addrs.push_back(str);
}
}
ASSERT_EQ(1, addrs.size());
}
TEST(ProcSelfMaps, MapUnmap) {
Mapping map1 = ASSERT_NO_ERRNO_AND_VALUE(
MmapAnon(kPageSize, PROT_READ | PROT_EXEC, MAP_PRIVATE));
Mapping map2 =
ASSERT_NO_ERRNO_AND_VALUE(MmapAnon(kPageSize, PROT_WRITE, MAP_PRIVATE));
auto proc_self_maps =
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/maps"));
std::vector<std::string> strings = absl::StrSplit(proc_self_maps, '\n');
std::vector<std::string> addrs;
// Make sure if is listed.
for (const auto& str : strings) {
if (str == AnonymousMapsEntryForMapping(map1, PROT_READ | PROT_EXEC)) {
addrs.push_back(str);
}
}
ASSERT_EQ(1, addrs.size()) << proc_self_maps;
addrs.clear();
for (const auto& str : strings) {
if (str == AnonymousMapsEntryForMapping(map2, PROT_WRITE)) {
addrs.push_back(str);
}
}
ASSERT_EQ(1, addrs.size());
map2.reset();
// Read it again.
proc_self_maps = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/maps"));
strings = absl::StrSplit(proc_self_maps, '\n');
// First entry should be there.
addrs.clear();
for (const auto& str : strings) {
if (str == AnonymousMapsEntryForMapping(map1, PROT_READ | PROT_EXEC)) {
addrs.push_back(str);
}
}
ASSERT_EQ(1, addrs.size());
addrs.clear();
// But not the second.
for (const auto& str : strings) {
if (str == AnonymousMapsEntryForMapping(map2, PROT_WRITE)) {
addrs.push_back(str);
}
}
ASSERT_EQ(0, addrs.size());
}
TEST(ProcSelfMaps, Mprotect) {
if (!IsRunningOnGvisor()) {
// FIXME: Linux's mprotect() sometimes fails to merge VMAs in this
// case.
LOG(WARNING) << "Skipping test on Linux";
return;
}
// Reserve 5 pages of address space.
Mapping m = ASSERT_NO_ERRNO_AND_VALUE(
MmapAnon(5 * kPageSize, PROT_NONE, MAP_PRIVATE));
// Change the permissions on the middle 3 pages. (The first and last pages may
// be merged with other vmas on either side, so they aren't tested directly;
// they just ensure that the middle 3 pages are bracketed by VMAs with
// incompatible permissions.)
ASSERT_THAT(mprotect(reinterpret_cast<void*>(m.addr() + kPageSize),
3 * kPageSize, PROT_READ),
SyscallSucceeds());
// Check that the middle 3 pages make up a single VMA.
auto proc_self_maps =
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/maps"));
std::vector<std::string> strings = absl::StrSplit(proc_self_maps, '\n');
EXPECT_THAT(strings, Contains(AnonymousMapsEntry(m.addr() + kPageSize,
3 * kPageSize, PROT_READ)));
// Change the permissions on the middle page only.
ASSERT_THAT(mprotect(reinterpret_cast<void*>(m.addr() + 2 * kPageSize),
kPageSize, PROT_READ | PROT_WRITE),
SyscallSucceeds());
// Check that the single VMA has been split into 3 VMAs.
proc_self_maps = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/maps"));
strings = absl::StrSplit(proc_self_maps, '\n');
EXPECT_THAT(
strings,
IsSupersetOf(
{AnonymousMapsEntry(m.addr() + kPageSize, kPageSize, PROT_READ),
AnonymousMapsEntry(m.addr() + 2 * kPageSize, kPageSize,
PROT_READ | PROT_WRITE),
AnonymousMapsEntry(m.addr() + 3 * kPageSize, kPageSize,
PROT_READ)}));
// Change the permissions on the middle page back.
ASSERT_THAT(mprotect(reinterpret_cast<void*>(m.addr() + 2 * kPageSize),
kPageSize, PROT_READ),
SyscallSucceeds());
// Check that the 3 VMAs have been merged back into a single VMA.
proc_self_maps = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/maps"));
strings = absl::StrSplit(proc_self_maps, '\n');
EXPECT_THAT(strings, Contains(AnonymousMapsEntry(m.addr() + kPageSize,
3 * kPageSize, PROT_READ)));
}
TEST(ProcSelfFd, OpenFd) {
int pipe_fds[2];
ASSERT_THAT(pipe2(pipe_fds, O_CLOEXEC), SyscallSucceeds());
// Reopen the write end.
const std::string path = absl::StrCat("/proc/self/fd/", pipe_fds[1]);
const FileDescriptor fd = ASSERT_NO_ERRNO_AND_VALUE(Open(path, O_WRONLY));
// Ensure that a read/write works.
const std::string data = "hello";
std::unique_ptr<char[]> buffer(new char[data.size()]);
EXPECT_THAT(write(fd.get(), data.c_str(), data.size()),
SyscallSucceedsWithValue(5));
EXPECT_THAT(read(pipe_fds[0], buffer.get(), data.size()),
SyscallSucceedsWithValue(5));
EXPECT_EQ(strncmp(buffer.get(), data.c_str(), data.size()), 0);
// Cleanup.
ASSERT_THAT(close(pipe_fds[0]), SyscallSucceeds());
ASSERT_THAT(close(pipe_fds[1]), SyscallSucceeds());
}
TEST(ProcSelfFdInfo, CorrectFds) {
// Make sure there is at least one open file.
auto f = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFile());
const FileDescriptor fd = ASSERT_NO_ERRNO_AND_VALUE(Open(f.path(), O_RDONLY));
// Get files in /proc/self/fd.
auto fd_files = ASSERT_NO_ERRNO_AND_VALUE(ListDir("/proc/self/fd", false));
// Get files in /proc/self/fdinfo.
auto fdinfo_files =
ASSERT_NO_ERRNO_AND_VALUE(ListDir("/proc/self/fdinfo", false));
// They should contain the same fds.
EXPECT_THAT(fd_files, UnorderedElementsAreArray(fdinfo_files));
// Both should contain fd.
auto fd_s = absl::StrCat(fd.get());
EXPECT_THAT(fd_files, Contains(fd_s));
}
TEST(ProcSelfFdInfo, Flags) {
std::string path = NewTempAbsPath();
// Create file here with O_CREAT to test that O_CREAT does not appear in
// fdinfo flags.
int flags = O_CREAT | O_RDWR | O_APPEND | O_CLOEXEC;
const FileDescriptor fd = ASSERT_NO_ERRNO_AND_VALUE(Open(path, flags, 0644));
// Automatically delete path.
TempPath temp_path(path);
// O_CREAT does not appear in fdinfo flags.
flags &= ~O_CREAT;
// O_LARGEFILE always appears (on x86_64).
flags |= kOLargeFile;
auto fd_info = ASSERT_NO_ERRNO_AND_VALUE(
GetContents(absl::StrCat("/proc/self/fdinfo/", fd.get())));
EXPECT_THAT(fd_info, HasSubstr(absl::StrFormat("flags:\t%#o", flags)));
}
TEST(ProcSelfExe, Absolute) {
auto exe = ASSERT_NO_ERRNO_AND_VALUE(
ReadLink(absl::StrCat("/proc/", getpid(), "/exe")));
EXPECT_EQ(exe[0], '/');
}
// Sanity check for /proc/cpuinfo fields that must be present.
TEST(ProcCpuinfo, RequiredFieldsArePresent) {
std::string proc_cpuinfo = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/cpuinfo"));
ASSERT_FALSE(proc_cpuinfo.empty());
std::vector<std::string> cpuinfo_fields = absl::StrSplit(proc_cpuinfo, '\n');
// This list of "required" fields is taken from reading the file
// arch/x86/kernel/cpu/proc.c and seeing which fields will be unconditionally
// printed by the kernel.
static const char* required_fields[] = {
"processor",
"vendor_id",
"cpu family",
"model\t\t:",
"model name",
"stepping",
"cpu MHz",
"fpu\t\t:",
"fpu_exception",
"cpuid level",
"wp",
"bogomips",
"clflush size",
"cache_alignment",
"address sizes",
"power management",
};
// Check that the usual fields are there. We don't really care about the
// contents.
for (const std::string& field : required_fields) {
EXPECT_THAT(proc_cpuinfo, HasSubstr(field));
}
}
// Sanity checks that uptime is present.
TEST(ProcUptime, IsPresent) {
std::string proc_uptime = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/uptime"));
ASSERT_FALSE(proc_uptime.empty());
std::vector<std::string> uptime_parts = absl::StrSplit(proc_uptime, ' ');
// Parse once.
double uptime0, uptime1, idletime0, idletime1;
ASSERT_TRUE(absl::SimpleAtod(uptime_parts[0], &uptime0));
ASSERT_TRUE(absl::SimpleAtod(uptime_parts[1], &idletime0));
// Sleep for one second.
absl::SleepFor(absl::Seconds(1));
// Parse again.
proc_uptime = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/uptime"));
ASSERT_FALSE(proc_uptime.empty());
uptime_parts = absl::StrSplit(proc_uptime, ' ');
ASSERT_TRUE(absl::SimpleAtod(uptime_parts[0], &uptime1));
ASSERT_TRUE(absl::SimpleAtod(uptime_parts[1], &idletime1));
// Sanity check.
//
// We assert that between 0.99 and 59.99 seconds have passed. If more than a
// minute has passed, then we must be executing really, really slowly.
EXPECT_GE(uptime0, 0.0);
EXPECT_GE(idletime0, 0.0);
EXPECT_GT(uptime1, uptime0);
EXPECT_GE(uptime1, uptime0 + 0.99);
EXPECT_LE(uptime1, uptime0 + 59.99);
EXPECT_GE(idletime1, idletime0);
}
TEST(ProcMeminfo, ContainsBasicFields) {
std::string proc_meminfo = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/meminfo"));
EXPECT_THAT(proc_meminfo, AllOf(ContainsRegex(R"(MemTotal:\s+[0-9]+ kB)"),
ContainsRegex(R"(MemFree:\s+[0-9]+ kB)")));
}
TEST(ProcStat, ContainsBasicFields) {
std::string proc_stat = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/stat"));
std::vector<std::string> names;
for (auto const& line : absl::StrSplit(proc_stat, '\n')) {
std::vector<std::string> fields =
absl::StrSplit(line, ' ', absl::SkipWhitespace());
if (fields.empty()) {
continue;
}
names.push_back(fields[0]);
}
EXPECT_THAT(names,
IsSupersetOf({"cpu", "intr", "ctxt", "btime", "processes",
"procs_running", "procs_blocked", "softirq"}));
}
TEST(ProcStat, EndsWithNewline) {
std::string proc_stat = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/stat"));
EXPECT_EQ(proc_stat.back(), '\n');
}
TEST(ProcStat, Fields) {
std::string proc_stat = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/stat"));
std::vector<std::string> names;
for (auto const& line : absl::StrSplit(proc_stat, '\n')) {
std::vector<std::string> fields =
absl::StrSplit(line, ' ', absl::SkipWhitespace());
if (fields.empty()) {
continue;
}
if (absl::StartsWith(fields[0], "cpu")) {
// As of Linux 3.11, each CPU entry has 10 fields, plus the name.
EXPECT_GE(fields.size(), 11) << proc_stat;
} else if (fields[0] == "ctxt") {
// Single field.
EXPECT_EQ(fields.size(), 2) << proc_stat;
} else if (fields[0] == "btime") {
// Single field.
EXPECT_EQ(fields.size(), 2) << proc_stat;
} else if (fields[0] == "itime") {
// Single field.
ASSERT_EQ(fields.size(), 2) << proc_stat;
// This is the only floating point field.
double val;
EXPECT_TRUE(absl::SimpleAtod(fields[1], &val)) << proc_stat;
continue;
} else if (fields[0] == "processes") {
// Single field.
EXPECT_EQ(fields.size(), 2) << proc_stat;
} else if (fields[0] == "procs_running") {
// Single field.
EXPECT_EQ(fields.size(), 2) << proc_stat;
} else if (fields[0] == "procs_blocked") {
// Single field.
EXPECT_EQ(fields.size(), 2) << proc_stat;
} else if (fields[0] == "softirq") {
// As of Linux 3.11, there are 10 softirqs. 12 fields for name + total.
EXPECT_GE(fields.size(), 12) << proc_stat;
}
// All fields besides itime are valid base 10 numbers.
for (size_t i = 1; i < fields.size(); i++) {
uint64_t val;
EXPECT_TRUE(absl::SimpleAtoi(fields[i], &val)) << proc_stat;
}
}
}
TEST(ProcLoadavg, EndsWithNewline) {
std::string proc_loadvg = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/loadavg"));
EXPECT_EQ(proc_loadvg.back(), '\n');
}
TEST(ProcLoadavg, Fields) {
std::string proc_loadvg = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/loadavg"));
std::vector<std::string> lines = absl::StrSplit(proc_loadvg, '\n');
// Single line.
EXPECT_EQ(lines.size(), 2) << proc_loadvg;
std::vector<std::string> fields =
absl::StrSplit(lines[0], absl::ByAnyChar(" /"), absl::SkipWhitespace());
// Six fields.
EXPECT_EQ(fields.size(), 6) << proc_loadvg;
double val;
uint64_t val2;
// First three fields are floating point numbers.
EXPECT_TRUE(absl::SimpleAtod(fields[0], &val)) << proc_loadvg;
EXPECT_TRUE(absl::SimpleAtod(fields[1], &val)) << proc_loadvg;
EXPECT_TRUE(absl::SimpleAtod(fields[2], &val)) << proc_loadvg;
// Rest of the fields are valid base 10 numbers.
EXPECT_TRUE(absl::SimpleAtoi(fields[3], &val2)) << proc_loadvg;
EXPECT_TRUE(absl::SimpleAtoi(fields[4], &val2)) << proc_loadvg;
EXPECT_TRUE(absl::SimpleAtoi(fields[5], &val2)) << proc_loadvg;
}
// NOTE: Tests in priority.cc also check certain priority related fields in
// /proc/self/stat.
class ProcPidStatTest : public ::testing::TestWithParam<std::string> {};
TEST_P(ProcPidStatTest, HasBasicFields) {
std::string proc_pid_stat = ASSERT_NO_ERRNO_AND_VALUE(
GetContents(absl::StrCat("/proc/", GetParam(), "/stat")));
ASSERT_FALSE(proc_pid_stat.empty());
std::vector<std::string> fields = absl::StrSplit(proc_pid_stat, ' ');
ASSERT_GE(fields.size(), 24);
EXPECT_EQ(absl::StrCat(getpid()), fields[0]);
// fields[1] is the thread name.
EXPECT_EQ("R", fields[2]); // task state
EXPECT_EQ(absl::StrCat(getppid()), fields[3]);
// If the test starts up quickly, then the process start time and the kernel
// boot time will be very close, and the proc starttime field (which is the
// delta of the two times) will be 0. For that unfortunate reason, we can
// only check that starttime >= 0, and not that it is strictly > 0.
uint64_t starttime;
ASSERT_TRUE(absl::SimpleAtoi(fields[21], &starttime));
EXPECT_GE(starttime, 0);
uint64_t vss;
ASSERT_TRUE(absl::SimpleAtoi(fields[22], &vss));
EXPECT_GT(vss, 0);
uint64_t rss;
ASSERT_TRUE(absl::SimpleAtoi(fields[23], &rss));
EXPECT_GT(rss, 0);
uint64_t rsslim;
ASSERT_TRUE(absl::SimpleAtoi(fields[24], &rsslim));
EXPECT_GT(rsslim, 0);
}
INSTANTIATE_TEST_CASE_P(SelfAndNumericPid, ProcPidStatTest,
::testing::Values("self", absl::StrCat(getpid())));
using ProcPidStatmTest = ::testing::TestWithParam<std::string>;
TEST_P(ProcPidStatmTest, HasBasicFields) {
std::string proc_pid_statm = ASSERT_NO_ERRNO_AND_VALUE(
GetContents(absl::StrCat("/proc/", GetParam(), "/statm")));
ASSERT_FALSE(proc_pid_statm.empty());
std::vector<std::string> fields = absl::StrSplit(proc_pid_statm, ' ');
ASSERT_GE(fields.size(), 7);
uint64_t vss;
ASSERT_TRUE(absl::SimpleAtoi(fields[0], &vss));
EXPECT_GT(vss, 0);
uint64_t rss;
ASSERT_TRUE(absl::SimpleAtoi(fields[1], &rss));
EXPECT_GT(rss, 0);
}
INSTANTIATE_TEST_CASE_P(SelfAndNumericPid, ProcPidStatmTest,
::testing::Values("self", absl::StrCat(getpid())));
PosixErrorOr<uint64_t> CurrentRSS() {
ASSIGN_OR_RETURN_ERRNO(auto proc_self_stat, GetContents("/proc/self/stat"));
if (proc_self_stat.empty()) {
return PosixError(EINVAL, "empty /proc/self/stat");
}
std::vector<std::string> fields = absl::StrSplit(proc_self_stat, ' ');
if (fields.size() < 24) {
return PosixError(
EINVAL,
absl::StrCat("/proc/self/stat has too few fields: ", proc_self_stat));
}
uint64_t rss;
if (!absl::SimpleAtoi(fields[23], &rss)) {
return PosixError(
EINVAL, absl::StrCat("/proc/self/stat RSS field is not a number: ",
fields[23]));
}
// RSS is given in number of pages.
return rss * kPageSize;
}
// The size of mapping created by MapPopulateRSS.
constexpr uint64_t kMappingSize = 100 << 20;
// Tolerance on RSS comparisons to account for background thread mappings,
// reclaimed pages, newly faulted pages, etc.
constexpr uint64_t kRSSTolerance = 5 << 20;
// Capture RSS before and after an anonymous mapping with passed prot.
void MapPopulateRSS(int prot, uint64_t* before, uint64_t* after) {
*before = ASSERT_NO_ERRNO_AND_VALUE(CurrentRSS());
// N.B. The kernel asynchronously accumulates per-task RSS counters into the
// mm RSS, which is exposed by /proc/PID/stat. Task exit is a synchronization
// point (kernel/exit.c:do_exit -> sync_mm_rss), so perform the mapping on
// another thread to ensure it is reflected in RSS after the thread exits.
Mapping mapping;
ScopedThread t([&mapping, prot] {
mapping = ASSERT_NO_ERRNO_AND_VALUE(
MmapAnon(kMappingSize, prot, MAP_PRIVATE | MAP_POPULATE));
});
t.Join();
*after = ASSERT_NO_ERRNO_AND_VALUE(CurrentRSS());
}
// TODO: Test for PROT_READ + MAP_POPULATE anonymous mappings. Their
// semantics are more subtle:
//
// Small pages -> Zero page mapped, not counted in RSS
// (mm/memory.c:do_anonymous_page).
//
// Huge pages (THP enabled, use_zero_page=0) -> Pages committed
// (mm/memory.c:__handle_mm_fault -> create_huge_pmd).
//
// Huge pages (THP enabled, use_zero_page=1) -> Zero page mapped, not counted in
// RSS (mm/huge_memory.c:do_huge_pmd_anonymous_page).
// PROT_WRITE + MAP_POPULATE anonymous mappings are always committed.
TEST(ProcSelfStat, PopulateWriteRSS) {
uint64_t before, after;
MapPopulateRSS(PROT_READ | PROT_WRITE, &before, &after);
// Mapping is committed.
EXPECT_NEAR(before + kMappingSize, after, kRSSTolerance);
}
// PROT_NONE + MAP_POPULATE anonymous mappings are never committed.
TEST(ProcSelfStat, PopulateNoneRSS) {
uint64_t before, after;
MapPopulateRSS(PROT_NONE, &before, &after);
// Mapping not committed.
EXPECT_NEAR(before, after, kRSSTolerance);
}
// Returns the calling thread's name.
PosixErrorOr<std::string> ThreadName() {
// "The buffer should allow space for up to 16 bytes; the returned std::string
// will be null-terminated if it is shorter than that." - prctl(2). But we
// always want the thread name to be null-terminated.
char thread_name[17];
int rc = prctl(PR_GET_NAME, thread_name, 0, 0, 0);
MaybeSave();
if (rc < 0) {
return PosixError(errno, "prctl(PR_GET_NAME)");
}
thread_name[16] = '\0';
return std::string(thread_name);
}
// Parses the contents of a /proc/[pid]/status file into a collection of
// key-value pairs.
PosixErrorOr<std::map<std::string, std::string>> ParseProcStatus(
absl::string_view status_str) {
std::map<std::string, std::string> fields;
for (absl::string_view const line :
absl::StrSplit(status_str, '\n', absl::SkipWhitespace())) {
const std::pair<absl::string_view, absl::string_view> kv =
absl::StrSplit(line, absl::MaxSplits(":\t", 1));
if (kv.first.empty()) {
return PosixError(
EINVAL, absl::StrCat("failed to parse key in line \"", line, "\""));
}
std::string key(kv.first);
if (fields.count(key)) {
return PosixError(EINVAL,
absl::StrCat("duplicate key \"", kv.first, "\""));
}
std::string value(kv.second);
absl::StripLeadingAsciiWhitespace(&value);
fields.emplace(std::move(key), std::move(value));
}
return fields;
}
TEST(ParseProcStatusTest, ParsesSimpleStatusFileWithMixedWhitespaceCorrectly) {
EXPECT_THAT(
ParseProcStatus(
"Name:\tinit\nState:\tS (sleeping)\nCapEff:\t 0000001fffffffff\n"),
IsPosixErrorOkAndHolds(UnorderedElementsAre(
Pair("Name", "init"), Pair("State", "S (sleeping)"),
Pair("CapEff", "0000001fffffffff"))));
}
TEST(ParseProcStatusTest, DetectsDuplicateKeys) {
auto proc_status_or = ParseProcStatus("Name:\tfoo\nName:\tfoo\n");
EXPECT_THAT(proc_status_or,
PosixErrorIs(EINVAL, ::testing::StrEq("duplicate key \"Name\"")));
}
TEST(ParseProcStatusTest, DetectsMissingTabs) {
EXPECT_THAT(ParseProcStatus("Name:foo\nPid: 1\n"),
IsPosixErrorOkAndHolds(UnorderedElementsAre(Pair("Name:foo", ""),
Pair("Pid: 1", ""))));
}
TEST(ProcPidStatusTest, HasBasicFields) {
// Do this on a separate thread since we want tgid != tid.
ScopedThread([] {
const pid_t tgid = getpid();
const pid_t tid = syscall(SYS_gettid);
EXPECT_NE(tgid, tid);
const auto thread_name = ASSERT_NO_ERRNO_AND_VALUE(ThreadName());
std::string status_str = ASSERT_NO_ERRNO_AND_VALUE(
GetContents(absl::StrCat("/proc/", tid, "/status")));
ASSERT_FALSE(status_str.empty());
const auto status = ASSERT_NO_ERRNO_AND_VALUE(ParseProcStatus(status_str));
EXPECT_THAT(status, IsSupersetOf({Pair("Name", thread_name),
Pair("Tgid", absl::StrCat(tgid)),
Pair("Pid", absl::StrCat(tid)),
Pair("PPid", absl::StrCat(getppid()))}));
});
}
TEST(ProcPidStatusTest, StateRunning) {
// Task must be running when reading the file.
const pid_t tid = syscall(SYS_gettid);
std::string status_str = ASSERT_NO_ERRNO_AND_VALUE(
GetContents(absl::StrCat("/proc/", tid, "/status")));
EXPECT_THAT(ParseProcStatus(status_str),
IsPosixErrorOkAndHolds(Contains(Pair("State", "R (running)"))));
}
TEST(ProcPidStatusTest, StateSleeping_NoRandomSave) {
// Starts a child process that blocks and checks that State is sleeping.
auto res = WithSubprocess(
[&](int pid) -> PosixError {
// Because this test is timing based we will disable cooperative saving
// and the test itself also has random saving disabled.
const DisableSave ds;
// Try multiple times in case the child isn't sleeping when status file
// is read.
MonotonicTimer timer;
timer.Start();
for (;;) {
ASSIGN_OR_RETURN_ERRNO(
std::string status_str,
GetContents(absl::StrCat("/proc/", pid, "/status")));
ASSIGN_OR_RETURN_ERRNO(auto map, ParseProcStatus(status_str));
if (map["State"] == std::string("S (sleeping)")) {
// Test passed!
return NoError();
}
if (timer.Duration() > absl::Seconds(10)) {
return PosixError(ETIMEDOUT, "Timeout waiting for child to sleep");
}
absl::SleepFor(absl::Milliseconds(10));
}
},
nullptr, nullptr);
ASSERT_NO_ERRNO(res);
}
TEST(ProcPidStatusTest, ValuesAreTabDelimited) {
std::string status_str =
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/status"));
ASSERT_FALSE(status_str.empty());
for (absl::string_view const line :
absl::StrSplit(status_str, '\n', absl::SkipWhitespace())) {
EXPECT_NE(std::string::npos, line.find(":\t"));
}
}
// Threads properly counts running threads.
//
// TODO: Test zombied threads while the thread group leader is still
// running with generalized fork and clone children from the wait test.
TEST(ProcPidStatusTest, Threads) {
char buf[4096] = {};
EXPECT_THAT(ReadWhileRunning("status", buf, sizeof(buf) - 1),
SyscallSucceedsWithValue(Gt(0)));
auto status = ASSERT_NO_ERRNO_AND_VALUE(ParseProcStatus(buf));
auto it = status.find("Threads");
ASSERT_NE(it, status.end());
int threads = -1;
EXPECT_TRUE(absl::SimpleAtoi(it->second, &threads))
<< "Threads value " << it->second << " is not a number";
// Don't make assumptions about the exact number of threads, as it may not be
// constant.
EXPECT_GE(threads, 1);
memset(buf, 0, sizeof(buf));
EXPECT_THAT(ReadWhileZombied("status", buf, sizeof(buf) - 1),
SyscallSucceedsWithValue(Gt(0)));
status = ASSERT_NO_ERRNO_AND_VALUE(ParseProcStatus(buf));
it = status.find("Threads");
ASSERT_NE(it, status.end());
threads = -1;
EXPECT_TRUE(absl::SimpleAtoi(it->second, &threads))
<< "Threads value " << it->second << " is not a number";
// There must be only the thread group leader remaining, zombied.
EXPECT_EQ(threads, 1);
}
// Returns true if all characters in s are digits.
bool IsDigits(absl::string_view s) {
return std::all_of(s.begin(), s.end(), absl::ascii_isdigit);
}
TEST(ProcPidStatTest, VSSRSS) {
std::string status_str =
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/status"));
ASSERT_FALSE(status_str.empty());
auto status = ASSERT_NO_ERRNO_AND_VALUE(ParseProcStatus(status_str));
const auto vss_it = status.find("VmSize");
ASSERT_NE(vss_it, status.end());
absl::string_view vss_str(vss_it->second);
// Room for the " kB" suffix plus at least one digit.
ASSERT_GT(vss_str.length(), 3);
EXPECT_TRUE(absl::EndsWith(vss_str, " kB"));
// Everything else is part of a number.
EXPECT_TRUE(IsDigits(vss_str.substr(0, vss_str.length() - 3))) << vss_str;
// ... which is not 0.
EXPECT_NE('0', vss_str[0]);
const auto rss_it = status.find("VmRSS");
ASSERT_NE(rss_it, status.end());
absl::string_view rss_str(rss_it->second);
// Room for the " kB" suffix plus at least one digit.
ASSERT_GT(rss_str.length(), 3);
EXPECT_TRUE(absl::EndsWith(rss_str, " kB"));
// Everything else is part of a number.
EXPECT_TRUE(IsDigits(rss_str.substr(0, rss_str.length() - 3))) << rss_str;
// ... which is not 0.
EXPECT_NE('0', rss_str[0]);
}
// Parse an array of NUL-terminated char* arrays, returning a vector of strings.
std::vector<std::string> ParseNulTerminatedStrings(std::string contents) {
EXPECT_EQ('\0', contents.back());
// The split will leave an empty std::string if the NUL-byte remains, so pop it.
contents.pop_back();
return absl::StrSplit(contents, '\0');
}
TEST(ProcPidCmdline, MatchesArgv) {
std::vector<std::string> proc_cmdline = ParseNulTerminatedStrings(
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/cmdline")));
EXPECT_THAT(saved_argv, ContainerEq(proc_cmdline));
}
TEST(ProcPidEnviron, MatchesEnviron) {
std::vector<std::string> proc_environ = ParseNulTerminatedStrings(
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/environ")));
// Get the environment from the environ variable, which we will compare with
// /proc/self/environ.
std::vector<std::string> env;
for (char** v = environ; *v; v++) {
env.push_back(*v);
}
EXPECT_THAT(env, ContainerEq(proc_environ));
}
TEST(ProcPidCmdline, SubprocessForkSameCmdline) {
std::vector<std::string> proc_cmdline_parent;
std::vector<std::string> proc_cmdline;
proc_cmdline_parent = ParseNulTerminatedStrings(
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/cmdline")));
auto res = WithSubprocess(
[&](int pid) -> PosixError {
ASSIGN_OR_RETURN_ERRNO(
auto raw_cmdline,
GetContents(absl::StrCat("/proc/", pid, "/cmdline")));
proc_cmdline = ParseNulTerminatedStrings(raw_cmdline);
return NoError();
},
nullptr, nullptr);
ASSERT_NO_ERRNO(res);
for (size_t i = 0; i < proc_cmdline_parent.size(); i++) {
EXPECT_EQ(proc_cmdline_parent[i], proc_cmdline[i]);
}
}
// Test whether /proc/PID/ symlinks can be read for a running process.
TEST(ProcPidSymlink, SubprocessRunning) {
char buf[1];
EXPECT_THAT(ReadlinkWhileRunning("exe", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadlinkWhileRunning("ns/net", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadlinkWhileRunning("ns/pid", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadlinkWhileRunning("ns/user", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
}
// FIXME: Inconsistent behavior between gVisor and linux
// on proc files.
TEST(ProcPidSymlink, SubprocessZombied) {
ASSERT_NO_ERRNO(SetCapability(CAP_DAC_OVERRIDE, false));
ASSERT_NO_ERRNO(SetCapability(CAP_DAC_READ_SEARCH, false));
char buf[1];
int want = EACCES;
if (!IsRunningOnGvisor()) {
auto version = ASSERT_NO_ERRNO_AND_VALUE(GetKernelVersion());
if (version.major == 4 && version.minor > 3) {
want = ENOENT;
}
}
EXPECT_THAT(ReadlinkWhileZombied("exe", buf, sizeof(buf)),
SyscallFailsWithErrno(want));
if (!IsRunningOnGvisor()) {
EXPECT_THAT(ReadlinkWhileZombied("ns/net", buf, sizeof(buf)),
SyscallFailsWithErrno(want));
}
// FIXME: Inconsistent behavior between gVisor and linux
// on proc files.
// 4.17 & gVisor: Syscall succeeds and returns 1
// EXPECT_THAT(ReadlinkWhileZombied("ns/pid", buf, sizeof(buf)),
// SyscallFailsWithErrno(EACCES));
// FIXME: Inconsistent behavior between gVisor and linux
// on proc files.
// 4.17 & gVisor: Syscall succeeds and returns 1.
// EXPECT_THAT(ReadlinkWhileZombied("ns/user", buf, sizeof(buf)),
// SyscallFailsWithErrno(EACCES));
}
// Test whether /proc/PID/ symlinks can be read for an exited process.
TEST(ProcPidSymlink, SubprocessExited) {
// FIXME: These all succeed on gVisor.
SKIP_IF(IsRunningOnGvisor());
char buf[1];
EXPECT_THAT(ReadlinkWhileExited("exe", buf, sizeof(buf)),
SyscallFailsWithErrno(ESRCH));
EXPECT_THAT(ReadlinkWhileExited("ns/net", buf, sizeof(buf)),
SyscallFailsWithErrno(ESRCH));
EXPECT_THAT(ReadlinkWhileExited("ns/pid", buf, sizeof(buf)),
SyscallFailsWithErrno(ESRCH));
EXPECT_THAT(ReadlinkWhileExited("ns/user", buf, sizeof(buf)),
SyscallFailsWithErrno(ESRCH));
}
// /proc/PID/exe points to the correct binary.
TEST(ProcPidExe, Subprocess) {
auto link = ASSERT_NO_ERRNO_AND_VALUE(ReadLink("/proc/self/exe"));
auto expected_absolute_path =
ASSERT_NO_ERRNO_AND_VALUE(MakeAbsolute(link, ""));
char actual[PATH_MAX + 1] = {};
ASSERT_THAT(ReadlinkWhileRunning("exe", actual, sizeof(actual)),
SyscallSucceedsWithValue(Gt(0)));
EXPECT_EQ(actual, expected_absolute_path);
}
// Test whether /proc/PID/ files can be read for a running process.
TEST(ProcPidFile, SubprocessRunning) {
char buf[1];
EXPECT_THAT(ReadWhileRunning("auxv", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadWhileRunning("cmdline", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadWhileRunning("comm", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadWhileRunning("gid_map", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadWhileRunning("io", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadWhileRunning("maps", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadWhileRunning("stat", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadWhileRunning("status", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadWhileRunning("uid_map", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
}
// Test whether /proc/PID/ files can be read for a zombie process.
TEST(ProcPidFile, SubprocessZombie) {
char buf[1];
// 4.17: Succeeds and returns 1
// gVisor: Succeeds and returns 0
EXPECT_THAT(ReadWhileZombied("auxv", buf, sizeof(buf)), SyscallSucceeds());
EXPECT_THAT(ReadWhileZombied("cmdline", buf, sizeof(buf)),
SyscallSucceedsWithValue(0));
EXPECT_THAT(ReadWhileZombied("comm", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadWhileZombied("gid_map", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadWhileZombied("maps", buf, sizeof(buf)),
SyscallSucceedsWithValue(0));
EXPECT_THAT(ReadWhileZombied("stat", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadWhileZombied("status", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
EXPECT_THAT(ReadWhileZombied("uid_map", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
// FIXME: Inconsistent behavior between gVisor and linux
// on proc files.
// gVisor & 4.17: Succeeds and returns 1.
// EXPECT_THAT(ReadWhileZombied("io", buf, sizeof(buf)),
// SyscallFailsWithErrno(EACCES));
}
// Test whether /proc/PID/ files can be read for an exited process.
TEST(ProcPidFile, SubprocessExited) {
char buf[1];
// FIXME: Inconsistent behavior between kernels
// gVisor: Fails with ESRCH.
// 4.17: Succeeds and returns 1.
// EXPECT_THAT(ReadWhileExited("auxv", buf, sizeof(buf)),
// SyscallFailsWithErrno(ESRCH));
EXPECT_THAT(ReadWhileExited("cmdline", buf, sizeof(buf)),
SyscallFailsWithErrno(ESRCH));
if (!IsRunningOnGvisor()) {
// FIXME: Succeeds on gVisor.
EXPECT_THAT(ReadWhileExited("comm", buf, sizeof(buf)),
SyscallFailsWithErrno(ESRCH));
}
EXPECT_THAT(ReadWhileExited("gid_map", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
if (!IsRunningOnGvisor()) {
// FIXME: Succeeds on gVisor.
EXPECT_THAT(ReadWhileExited("io", buf, sizeof(buf)),
SyscallFailsWithErrno(ESRCH));
}
if (!IsRunningOnGvisor()) {
// FIXME: Returns EOF on gVisor.
EXPECT_THAT(ReadWhileExited("maps", buf, sizeof(buf)),
SyscallFailsWithErrno(ESRCH));
}
if (!IsRunningOnGvisor()) {
// FIXME: Succeeds on gVisor.
EXPECT_THAT(ReadWhileExited("stat", buf, sizeof(buf)),
SyscallFailsWithErrno(ESRCH));
}
if (!IsRunningOnGvisor()) {
// FIXME: Succeeds on gVisor.
EXPECT_THAT(ReadWhileExited("status", buf, sizeof(buf)),
SyscallFailsWithErrno(ESRCH));
}
EXPECT_THAT(ReadWhileExited("uid_map", buf, sizeof(buf)),
SyscallSucceedsWithValue(sizeof(buf)));
}
PosixError DirContainsImpl(absl::string_view path,
const std::vector<std::string>& targets, bool strict) {
ASSIGN_OR_RETURN_ERRNO(auto listing, ListDir(path, false));
bool success = true;
for (auto& expected_entry : targets) {
auto cursor = std::find(listing.begin(), listing.end(), expected_entry);
if (cursor == listing.end()) {
success = false;
}
}
if (!success) {
return PosixError(
ENOENT,
absl::StrCat("Failed to find one or more paths in '", path, "'"));
}
if (strict) {
if (targets.size() != listing.size()) {
return PosixError(
EINVAL,
absl::StrCat("Expected to find ", targets.size(), " elements in '",
path, "', but found ", listing.size()));
}
}
return NoError();
}
PosixError DirContains(absl::string_view path,
const std::vector<std::string>& targets) {
return DirContainsImpl(path, targets, false);
}
PosixError DirContainsExactly(absl::string_view path,
const std::vector<std::string>& targets) {
return DirContainsImpl(path, targets, true);
}
PosixError EventuallyDirContainsExactly(absl::string_view path,
const std::vector<std::string>& targets) {
constexpr int kRetryCount = 100;
const absl::Duration kRetryDelay = absl::Milliseconds(100);
for (int i = 0; i < kRetryCount; ++i) {
auto res = DirContainsExactly(path, targets);
if (res.ok()) {
return res;
} else if (i < kRetryCount - 1) {
// Sleep if this isn't the final iteration.
absl::SleepFor(kRetryDelay);
}
}
return PosixError(ETIMEDOUT,
"Timed out while waiting for directory to contain files ");
}
TEST(ProcTask, Basic) {
EXPECT_NO_ERRNO(
DirContains("/proc/self/task", {".", "..", absl::StrCat(getpid())}));
}
std::vector<std::string> TaskFiles(const std::vector<std::string>& initial_contents,
const std::vector<pid_t>& pids) {
return VecCat<std::string>(
initial_contents,
ApplyVec<std::string>([](const pid_t p) { return absl::StrCat(p); }, pids));
}
std::vector<std::string> TaskFiles(const std::vector<pid_t>& pids) {
return TaskFiles({".", "..", absl::StrCat(getpid())}, pids);
}
// Helper class for creating a new task in the current thread group.
class BlockingChild {
public:
BlockingChild() : thread_([=] { Start(); }) {}
~BlockingChild() { Join(); }
pid_t Tid() const {
absl::MutexLock ml(&mu_);
mu_.Await(absl::Condition(&tid_ready_));
return tid_;
}
void Join() { Stop(); }
private:
void Start() {
absl::MutexLock ml(&mu_);
tid_ = syscall(__NR_gettid);
tid_ready_ = true;
mu_.Await(absl::Condition(&stop_));
}
void Stop() {
absl::MutexLock ml(&mu_);
stop_ = true;
}
mutable absl::Mutex mu_;
bool stop_ GUARDED_BY(mu_) = false;
pid_t tid_;
bool tid_ready_ GUARDED_BY(mu_) = false;
// Must be last to ensure that the destructor for the thread is run before
// any other member of the object is destroyed.
ScopedThread thread_;
};
TEST(ProcTask, NewThreadAppears) {
auto initial = ASSERT_NO_ERRNO_AND_VALUE(ListDir("/proc/self/task", false));
BlockingChild child1;
EXPECT_NO_ERRNO(DirContainsExactly("/proc/self/task",
TaskFiles(initial, {child1.Tid()})));
}
TEST(ProcTask, KilledThreadsDisappear) {
auto initial = ASSERT_NO_ERRNO_AND_VALUE(ListDir("/proc/self/task/", false));
BlockingChild child1;
EXPECT_NO_ERRNO(DirContainsExactly("/proc/self/task",
TaskFiles(initial, {child1.Tid()})));
// Stat child1's task file.
struct stat statbuf;
const std::string child1_task_file =
absl::StrCat("/proc/self/task/", child1.Tid());
EXPECT_THAT(stat(child1_task_file.c_str(), &statbuf), SyscallSucceeds());
BlockingChild child2;
EXPECT_NO_ERRNO(DirContainsExactly(
"/proc/self/task", TaskFiles(initial, {child1.Tid(), child2.Tid()})));
BlockingChild child3;
BlockingChild child4;
BlockingChild child5;
EXPECT_NO_ERRNO(DirContainsExactly(
"/proc/self/task",
TaskFiles(initial, {child1.Tid(), child2.Tid(), child3.Tid(),
child4.Tid(), child5.Tid()})));
child2.Join();
EXPECT_NO_ERRNO(EventuallyDirContainsExactly(
"/proc/self/task", TaskFiles(initial, {child1.Tid(), child3.Tid(),
child4.Tid(), child5.Tid()})));
child1.Join();
child4.Join();
EXPECT_NO_ERRNO(EventuallyDirContainsExactly(
"/proc/self/task", TaskFiles(initial, {child3.Tid(), child5.Tid()})));
// Stat child1's task file again. This time it should fail.
EXPECT_THAT(stat(child1_task_file.c_str(), &statbuf),
SyscallFailsWithErrno(ENOENT));
child3.Join();
child5.Join();
EXPECT_NO_ERRNO(EventuallyDirContainsExactly("/proc/self/task", initial));
}
TEST(ProcTask, ChildTaskDir) {
BlockingChild child1;
EXPECT_NO_ERRNO(DirContains("/proc/self/task", TaskFiles({child1.Tid()})));
EXPECT_NO_ERRNO(DirContains(absl::StrCat("/proc/", child1.Tid(), "/task"),
TaskFiles({child1.Tid()})));
}
PosixError VerifyPidDir(std::string path) {
return DirContains(path, {"exe", "fd", "io", "maps", "ns", "stat", "status"});
}
TEST(ProcTask, VerifyTaskDir) {
EXPECT_NO_ERRNO(VerifyPidDir("/proc/self"));
EXPECT_NO_ERRNO(VerifyPidDir(absl::StrCat("/proc/self/task/", getpid())));
BlockingChild child1;
EXPECT_NO_ERRNO(VerifyPidDir(absl::StrCat("/proc/self/task/", child1.Tid())));
// Only the first level of task directories should contain the 'task'
// directory. That is:
//
// /proc/1234/task <- should exist
// /proc/1234/task/1234/task <- should not exist
// /proc/1234/task/1235/task <- should not exist (where 1235 is in the same
// thread group as 1234).
EXPECT_FALSE(
DirContains(absl::StrCat("/proc/self/task/", getpid()), {"task"}).ok())
<< "Found 'task' directory in an inner directory.";
}
TEST(ProcTask, TaskDirCannotBeDeleted) {
// Drop capabilities that allow us to override file and directory permissions.
ASSERT_NO_ERRNO(SetCapability(CAP_DAC_OVERRIDE, false));
EXPECT_THAT(rmdir("/proc/self/task"), SyscallFails());
EXPECT_THAT(rmdir(absl::StrCat("/proc/self/task/", getpid()).c_str()),
SyscallFailsWithErrno(EACCES));
}
TEST(ProcTask, TaskDirHasCorrectMetadata) {
struct stat st;
EXPECT_THAT(stat("/proc/self/task", &st), SyscallSucceeds());
EXPECT_TRUE(S_ISDIR(st.st_mode));
// Verify file is readable and executable by everyone.
mode_t expected_permissions =
S_IRUSR | S_IXUSR | S_IRGRP | S_IXGRP | S_IROTH | S_IXOTH;
mode_t permissions = st.st_mode & (S_IRWXU | S_IRWXG | S_IRWXO);
EXPECT_EQ(expected_permissions, permissions);
}
TEST(ProcTask, TaskDirCanSeekToEnd) {
const FileDescriptor dirfd =
ASSERT_NO_ERRNO_AND_VALUE(Open("/proc/self/task", O_RDONLY));
EXPECT_THAT(lseek(dirfd.get(), 0, SEEK_END), SyscallSucceeds());
}
TEST(ProcTask, VerifyTaskDirNlinks) {
// A task directory will have 3 links if the taskgroup has a single
// thread. For example, the following shows where the links to
// '/proc/12345/task comes' from for a single threaded process with pid 12345:
//
// /proc/12345/task <-- 1 link for the directory itself
// . <-- link from "."
// ..
// 12345
// .
// .. <-- link from ".." to parent.
// <other contents of a task dir>
//
// We can't assert an absolute number of links since we don't control how many
// threads the test framework spawns. Instead, we'll ensure creating a new
// thread increases the number of links as expected.
// Once we reach the test body, we can count on the thread count being stable
// unless we spawn a new one.
uint64_t initial_links = ASSERT_NO_ERRNO_AND_VALUE(Links("/proc/self/task"));
ASSERT_GE(initial_links, 3);
// For each new subtask, we should gain a new link.
BlockingChild child1;
EXPECT_THAT(Links("/proc/self/task"),
IsPosixErrorOkAndHolds(initial_links + 1));
BlockingChild child2;
EXPECT_THAT(Links("/proc/self/task"),
IsPosixErrorOkAndHolds(initial_links + 2));
}
TEST(ProcTask, CommContainsThreadNameAndTrailingNewline) {
constexpr char kThreadName[] = "TestThread12345";
ASSERT_THAT(prctl(PR_SET_NAME, kThreadName), SyscallSucceeds());
auto thread_name = ASSERT_NO_ERRNO_AND_VALUE(
GetContents(JoinPath("/proc", absl::StrCat(getpid()), "task",
absl::StrCat(syscall(SYS_gettid)), "comm")));
EXPECT_EQ(absl::StrCat(kThreadName, "\n"), thread_name);
}
TEST(ProcTaskNs, NsDirExistsAndHasCorrectMetadata) {
EXPECT_NO_ERRNO(DirContains("/proc/self/ns", {"net", "pid", "user"}));
// Let's just test the 'pid' entry, all of them are very similar.
struct stat st;
EXPECT_THAT(lstat("/proc/self/ns/pid", &st), SyscallSucceeds());
EXPECT_TRUE(S_ISLNK(st.st_mode));
auto link = ASSERT_NO_ERRNO_AND_VALUE(ReadLink("/proc/self/ns/pid"));
EXPECT_THAT(link, ::testing::StartsWith("pid:["));
}
TEST(ProcTaskNs, AccessOnNsNodeSucceeds) {
EXPECT_THAT(access("/proc/self/ns/pid", F_OK), SyscallSucceeds());
}
TEST(ProcSysKernelHostname, Exists) {
EXPECT_THAT(open("/proc/sys/kernel/hostname", O_RDONLY), SyscallSucceeds());
}
TEST(ProcSysKernelHostname, MatchesUname) {
struct utsname buf;
EXPECT_THAT(uname(&buf), SyscallSucceeds());
const std::string hostname = absl::StrCat(buf.nodename, "\n");
auto procfs_hostname =
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/sys/kernel/hostname"));
EXPECT_EQ(procfs_hostname, hostname);
}
TEST(ProcSysVmMmapMinAddr, HasNumericValue) {
const std::string mmap_min_addr_str =
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/sys/vm/mmap_min_addr"));
uintptr_t mmap_min_addr;
EXPECT_TRUE(absl::SimpleAtoi(mmap_min_addr_str, &mmap_min_addr))
<< "/proc/sys/vm/mmap_min_addr does not contain a numeric value: "
<< mmap_min_addr_str;
}
TEST(ProcSysVmOvercommitMemory, HasNumericValue) {
const std::string overcommit_memory_str =
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/sys/vm/overcommit_memory"));
uintptr_t overcommit_memory;
EXPECT_TRUE(absl::SimpleAtoi(overcommit_memory_str, &overcommit_memory))
<< "/proc/sys/vm/overcommit_memory does not contain a numeric value: "
<< overcommit_memory;
}
// Check that link for proc fd entries point the target node, not the
// symlink itself.
TEST(ProcTaskFd, FstatatFollowsSymlink) {
const TempPath file = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFile());
const FileDescriptor fd =
ASSERT_NO_ERRNO_AND_VALUE(Open(file.path(), O_RDONLY));
struct stat sproc = {};
EXPECT_THAT(
fstatat(-1, absl::StrCat("/proc/self/fd/", fd.get()).c_str(), &sproc, 0),
SyscallSucceeds());
struct stat sfile = {};
EXPECT_THAT(fstatat(-1, file.path().c_str(), &sfile, 0), SyscallSucceeds());
// If fstatat follows the fd symlink, the device and inode numbers should
// match at a minimum.
EXPECT_EQ(sproc.st_dev, sfile.st_dev);
EXPECT_EQ(sproc.st_ino, sfile.st_ino);
EXPECT_EQ(0, memcmp(&sfile, &sproc, sizeof(sfile)));
}
TEST(ProcFilesystems, Bug65172365) {
std::string proc_filesystems =
ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/filesystems"));
ASSERT_FALSE(proc_filesystems.empty());
}
TEST(ProcFilesystems, PresenceOfShmMaxMniAll) {
uint64_t shmmax = 0;
uint64_t shmall = 0;
uint64_t shmmni = 0;
std::string proc_file;
proc_file = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/sys/kernel/shmmax"));
ASSERT_FALSE(proc_file.empty());
ASSERT_TRUE(absl::SimpleAtoi(proc_file, &shmmax));
proc_file = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/sys/kernel/shmall"));
ASSERT_FALSE(proc_file.empty());
ASSERT_TRUE(absl::SimpleAtoi(proc_file, &shmall));
proc_file = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/sys/kernel/shmmni"));
ASSERT_FALSE(proc_file.empty());
ASSERT_TRUE(absl::SimpleAtoi(proc_file, &shmmni));
ASSERT_GT(shmmax, 0);
ASSERT_GT(shmall, 0);
ASSERT_GT(shmmni, 0);
ASSERT_LE(shmall, shmmax);
// These values should never be higher than this by default, for more
// information see uapi/linux/shm.h
ASSERT_LE(shmmax, ULONG_MAX - (1UL << 24));
ASSERT_LE(shmall, ULONG_MAX - (1UL << 24));
}
// Check that /proc/mounts is a symlink to self/mounts.
TEST(ProcMounts, IsSymlink) {
auto link = ASSERT_NO_ERRNO_AND_VALUE(ReadLink("/proc/mounts"));
EXPECT_EQ(link, "self/mounts");
}
// Check that /proc/self/mounts looks something like a real mounts file.
TEST(ProcSelfMounts, RequiredFieldsArePresent) {
auto mounts = ASSERT_NO_ERRNO_AND_VALUE(GetContents("/proc/self/mounts"));
EXPECT_THAT(mounts,
AllOf(
// Root mount.
ContainsRegex(R"(\S+ / \S+ (rw|ro)\S* [0-9]+ [0-9]+\s)"),
// Root mount.
ContainsRegex(R"(\S+ /proc \S+ rw\S* [0-9]+ [0-9]+\s)")));
}
} // namespace
} // namespace testing
} // namespace gvisor
int main(int argc, char** argv) {
for (int i = 0; i < argc; ++i) {
gvisor::testing::saved_argv.emplace_back(std::string(argv[i]));
}
gvisor::testing::TestInit(&argc, &argv);
return RUN_ALL_TESTS();
}
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