// Copyright 2014 The Crashpad Authors. All rights reserved. // // 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 "util/posix/process_info.h" #include #include #include #include #include #include #include "base/strings/string_number_conversions.h" #include "base/strings/stringprintf.h" #include "build/build_config.h" #include "gtest/gtest.h" #include "test/errors.h" #include "test/main_arguments.h" #include "test/multiprocess.h" #include "util/file/file_io.h" #include "util/misc/implicit_cast.h" #include "util/string/split_string.h" #if defined(OS_LINUX) || defined(OS_CHROMEOS) || defined(OS_ANDROID) #include "util/linux/direct_ptrace_connection.h" #include "test/linux/fake_ptrace_connection.h" #endif namespace crashpad { namespace test { namespace { void TestProcessSelfOrClone(const ProcessInfo& process_info) { // There’s no system call to obtain the saved set-user ID or saved set-group // ID in an easy way. Normally, they are the same as the effective user ID and // effective group ID, so just check against those. EXPECT_EQ(process_info.RealUserID(), getuid()); const uid_t euid = geteuid(); EXPECT_EQ(process_info.EffectiveUserID(), euid); EXPECT_EQ(process_info.SavedUserID(), euid); const gid_t gid = getgid(); EXPECT_EQ(process_info.RealGroupID(), gid); const gid_t egid = getegid(); EXPECT_EQ(process_info.EffectiveGroupID(), egid); EXPECT_EQ(process_info.SavedGroupID(), egid); // Test SupplementaryGroups(). int group_count = getgroups(0, nullptr); ASSERT_GE(group_count, 0) << ErrnoMessage("getgroups"); std::vector group_vector(group_count); if (group_count > 0) { group_count = getgroups(group_vector.size(), &group_vector[0]); ASSERT_GE(group_count, 0) << ErrnoMessage("getgroups"); ASSERT_EQ(implicit_cast(group_count), group_vector.size()); } std::set group_set(group_vector.begin(), group_vector.end()); EXPECT_EQ(process_info.SupplementaryGroups(), group_set); // Test AllGroups(), which is SupplementaryGroups() plus the real, effective, // and saved set-group IDs. The effective and saved set-group IDs are expected // to be identical (see above). group_set.insert(gid); group_set.insert(egid); EXPECT_EQ(process_info.AllGroups(), group_set); // The test executable isn’t expected to change privileges. EXPECT_FALSE(process_info.DidChangePrivileges()); #if defined(ARCH_CPU_64_BITS) EXPECT_TRUE(process_info.Is64Bit()); #else EXPECT_FALSE(process_info.Is64Bit()); #endif // Test StartTime(). This program must have started at some time in the past. timeval start_time; ASSERT_TRUE(process_info.StartTime(&start_time)); EXPECT_FALSE(start_time.tv_sec == 0 && start_time.tv_usec == 0); time_t now; time(&now); EXPECT_LE(start_time.tv_sec, now); const std::vector& expect_argv = GetMainArguments(); #if defined(OS_ANDROID) || defined(OS_LINUX) || defined(OS_CHROMEOS) // Prior to Linux 4.2, the kernel only allowed reading a single page from // /proc//cmdline, causing any further arguments to be truncated. Disable // testing arguments in this case. // TODO(jperaza): The main arguments are stored on the main thread's stack // (and so should be included in dumps automatically), and // ProcessInfo::Arguments() might be updated to read the arguments directly, // rather than via procfs on older kernels. utsname uts; ASSERT_EQ(uname(&uts), 0) << ErrnoMessage("uname"); std::vector parts = SplitString(uts.release, '.'); ASSERT_GE(parts.size(), 2u); int major, minor; ASSERT_TRUE(base::StringToInt(parts[0], &major)); ASSERT_TRUE(base::StringToInt(parts[1], &minor)); size_t argv_size = 0; for (const auto& arg : expect_argv) { argv_size += arg.size() + 1; } if ((major < 4 || (major == 4 && minor < 2)) && argv_size > static_cast(getpagesize())) { return; } #endif // OS_ANDROID || OS_LINUX || OS_CHROMEOS std::vector argv; ASSERT_TRUE(process_info.Arguments(&argv)); // expect_argv always contains the initial view of the arguments at the time // the program was invoked. argv may contain this view, or it may contain the // current view of arguments after Google Test argv processing. argv may be a // subset of expect_argv. // // Google Test argv processing always leaves argv[0] intact, so this can be // checked directly. ASSERT_FALSE(expect_argv.empty()); ASSERT_FALSE(argv.empty()); EXPECT_EQ(argv[0], expect_argv[0]); EXPECT_LE(argv.size(), expect_argv.size()); // Everything else in argv should have a match in expect_argv too, but things // may have moved around. for (size_t arg_index = 1; arg_index < argv.size(); ++arg_index) { const std::string& arg = argv[arg_index]; SCOPED_TRACE( base::StringPrintf("arg_index %zu, arg %s", arg_index, arg.c_str())); EXPECT_NE(expect_argv.end(), std::find(argv.begin(), argv.end(), arg)); } } void TestSelfProcess(const ProcessInfo& process_info) { EXPECT_EQ(process_info.ProcessID(), getpid()); EXPECT_EQ(process_info.ParentProcessID(), getppid()); TestProcessSelfOrClone(process_info); } TEST(ProcessInfo, Self) { ProcessInfo process_info; #if defined(OS_LINUX) || defined(OS_CHROMEOS) || defined(OS_ANDROID) FakePtraceConnection connection; ASSERT_TRUE(connection.Initialize(getpid())); ASSERT_TRUE(process_info.InitializeWithPtrace(&connection)); #else ASSERT_TRUE(process_info.InitializeWithPid(getpid())); #endif // OS_LINUX || OS_ANDROID || OS_CHROMEOS TestSelfProcess(process_info); } #if defined(OS_APPLE) TEST(ProcessInfo, SelfTask) { ProcessInfo process_info; ASSERT_TRUE(process_info.InitializeWithTask(mach_task_self())); TestSelfProcess(process_info); } #endif TEST(ProcessInfo, Pid1) { // PID 1 is expected to be init or the system’s equivalent. This tests reading // information about another process. ProcessInfo process_info; #if defined(OS_LINUX) || defined(OS_CHROMEOS) || defined(OS_ANDROID) FakePtraceConnection connection; ASSERT_TRUE(connection.Initialize(1)); ASSERT_TRUE(process_info.InitializeWithPtrace(&connection)); #else ASSERT_TRUE(process_info.InitializeWithPid(1)); #endif EXPECT_EQ(process_info.ProcessID(), implicit_cast(1)); EXPECT_EQ(process_info.ParentProcessID(), implicit_cast(0)); EXPECT_EQ(process_info.RealUserID(), implicit_cast(0)); EXPECT_EQ(process_info.EffectiveUserID(), implicit_cast(0)); EXPECT_EQ(process_info.SavedUserID(), implicit_cast(0)); EXPECT_EQ(process_info.RealGroupID(), implicit_cast(0)); EXPECT_EQ(process_info.EffectiveGroupID(), implicit_cast(0)); EXPECT_EQ(process_info.SavedGroupID(), implicit_cast(0)); EXPECT_FALSE(process_info.AllGroups().empty()); } class ProcessInfoForkedTest : public Multiprocess { public: ProcessInfoForkedTest() : Multiprocess() {} ProcessInfoForkedTest(const ProcessInfoForkedTest&) = delete; ProcessInfoForkedTest& operator=(const ProcessInfoForkedTest&) = delete; ~ProcessInfoForkedTest() {} // Multiprocess: void MultiprocessParent() override { const pid_t pid = ChildPID(); #if defined(OS_LINUX) || defined(OS_CHROMEOS) || defined(OS_ANDROID) DirectPtraceConnection connection; ASSERT_TRUE(connection.Initialize(pid)); ProcessInfo process_info; ASSERT_TRUE(process_info.InitializeWithPtrace(&connection)); #else ProcessInfo process_info; ASSERT_TRUE(process_info.InitializeWithPid(pid)); #endif // OS_LINUX || OS_CHROMEOS || OS_ANDROID EXPECT_EQ(process_info.ProcessID(), pid); EXPECT_EQ(process_info.ParentProcessID(), getpid()); TestProcessSelfOrClone(process_info); } void MultiprocessChild() override { // Hang around until the parent is done. CheckedReadFileAtEOF(ReadPipeHandle()); } }; TEST(ProcessInfo, Forked) { ProcessInfoForkedTest test; test.Run(); } } // namespace } // namespace test } // namespace crashpad