ClickHouse/dbms/src/Common/ShellCommand.cpp
proller caf83a650e libs: compiling with msvc2017 (#1996)
* Allow use bundled *ssl library

* fix

* Add submodule

* Fixes

* fix

* fixes

* fixes

* fix

* fix

* update poco

* fix warnings

* fix

* fix

* Build fixes

* Build fixes

* fix

* fix

* fix

* fix

* fix

* fix

* fix

* add bat

* no zookeeper in dbms

* update boost

* fixes

* fixes

* fix

* fix

* fix

* fix

* try fix

* try fix

* fix

* fix

* fix

* fix

* fix

* fix

* fix

* fix

* Better

* fix

* dh verbose

* fix

* dh verbose

* fix

* clean

* Update LocalDate.h

* Update LocalDateTime.h
2018-03-23 19:05:14 +03:00

226 lines
7.2 KiB
C++

#include <sys/types.h>
#include <sys/wait.h>
#include <fcntl.h>
#include <dlfcn.h>
#include <Common/Exception.h>
#include <Common/ShellCommand.h>
#include <IO/WriteBufferFromVector.h>
#include <IO/WriteHelpers.h>
#include <port/unistd.h>
namespace DB
{
namespace ErrorCodes
{
extern const int CANNOT_PIPE;
extern const int CANNOT_DLSYM;
extern const int CANNOT_FORK;
extern const int CANNOT_WAITPID;
extern const int CHILD_WAS_NOT_EXITED_NORMALLY;
extern const int CANNOT_CREATE_CHILD_PROCESS;
}
}
namespace
{
struct Pipe
{
union
{
int fds[2];
struct
{
int read_fd;
int write_fd;
};
};
Pipe()
{
#ifndef __APPLE__
if (0 != pipe2(fds, O_CLOEXEC))
DB::throwFromErrno("Cannot create pipe", DB::ErrorCodes::CANNOT_PIPE);
#else
if (0 != pipe(fds))
DB::throwFromErrno("Cannot create pipe", DB::ErrorCodes::CANNOT_PIPE);
if (0 != fcntl(fds[0], F_SETFD, FD_CLOEXEC))
DB::throwFromErrno("Cannot create pipe", DB::ErrorCodes::CANNOT_PIPE);
if (0 != fcntl(fds[1], F_SETFD, FD_CLOEXEC))
DB::throwFromErrno("Cannot create pipe", DB::ErrorCodes::CANNOT_PIPE);
#endif
}
~Pipe()
{
if (read_fd >= 0)
close(read_fd);
if (write_fd >= 0)
close(write_fd);
}
};
/// By these return codes from the child process, we learn (for sure) about errors when creating it.
enum class ReturnCodes : int
{
CANNOT_DUP_STDIN = 0x55555555, /// The value is not important, but it is chosen so that it's rare to conflict with the program return code.
CANNOT_DUP_STDOUT = 0x55555556,
CANNOT_DUP_STDERR = 0x55555557,
CANNOT_EXEC = 0x55555558,
};
}
namespace DB
{
ShellCommand::~ShellCommand()
{
if (!wait_called)
tryWait();
}
std::unique_ptr<ShellCommand> ShellCommand::executeImpl(const char * filename, char * const argv[], bool pipe_stdin_only)
{
/** Here it is written that with a normal call `vfork`, there is a chance of deadlock in multithreaded programs,
* because of the resolving of characters in the shared library
* http://www.oracle.com/technetwork/server-storage/solaris10/subprocess-136439.html
* Therefore, separate the resolving of the symbol from the call.
*/
static void * real_vfork = dlsym(RTLD_DEFAULT, "vfork");
if (!real_vfork)
throwFromErrno("Cannot find symbol vfork in myself", ErrorCodes::CANNOT_DLSYM);
Pipe pipe_stdin;
Pipe pipe_stdout;
Pipe pipe_stderr;
pid_t pid = reinterpret_cast<pid_t(*)()>(real_vfork)();
if (-1 == pid)
throwFromErrno("Cannot vfork", ErrorCodes::CANNOT_FORK);
if (0 == pid)
{
/// We are in the freshly created process.
/// Why `_exit` and not `exit`? Because `exit` calls `atexit` and destructors of thread local storage.
/// And there is a lot of garbage (including, for example, mutex is blocked). And this can not be done after `vfork` - deadlock happens.
/// Replace the file descriptors with the ends of our pipes.
if (STDIN_FILENO != dup2(pipe_stdin.read_fd, STDIN_FILENO))
_exit(int(ReturnCodes::CANNOT_DUP_STDIN));
if (!pipe_stdin_only)
{
if (STDOUT_FILENO != dup2(pipe_stdout.write_fd, STDOUT_FILENO))
_exit(int(ReturnCodes::CANNOT_DUP_STDOUT));
if (STDERR_FILENO != dup2(pipe_stderr.write_fd, STDERR_FILENO))
_exit(int(ReturnCodes::CANNOT_DUP_STDERR));
}
execv(filename, argv);
/// If the process is running, then `execv` does not return here.
_exit(int(ReturnCodes::CANNOT_EXEC));
}
std::unique_ptr<ShellCommand> res(new ShellCommand(pid, pipe_stdin.write_fd, pipe_stdout.read_fd, pipe_stderr.read_fd));
/// Now the ownership of the file descriptors is passed to the result.
pipe_stdin.write_fd = -1;
pipe_stdout.read_fd = -1;
pipe_stderr.read_fd = -1;
return res;
}
std::unique_ptr<ShellCommand> ShellCommand::execute(const std::string & command, bool pipe_stdin_only)
{
/// Arguments in non-constant chunks of memory (as required for `execv`).
/// Moreover, their copying must be done before calling `vfork`, so after `vfork` do a minimum of things.
std::vector<char> argv0("sh", "sh" + strlen("sh") + 1);
std::vector<char> argv1("-c", "-c" + strlen("-c") + 1);
std::vector<char> argv2(command.data(), command.data() + command.size() + 1);
char * const argv[] = { argv0.data(), argv1.data(), argv2.data(), nullptr };
return executeImpl("/bin/sh", argv, pipe_stdin_only);
}
std::unique_ptr<ShellCommand> ShellCommand::executeDirect(const std::string & path, const std::vector<std::string> & arguments)
{
size_t argv_sum_size = path.size() + 1;
for (const auto & arg : arguments)
argv_sum_size += arg.size() + 1;
std::vector<char *> argv(arguments.size() + 2);
std::vector<char> argv_data(argv_sum_size);
WriteBuffer writer(argv_data.data(), argv_sum_size);
argv[0] = writer.position();
writer.write(path.data(), path.size() + 1);
for (size_t i = 0, size = arguments.size(); i < size; ++i)
{
argv[i + 1] = writer.position();
writer.write(arguments[i].data(), arguments[i].size() + 1);
}
argv[arguments.size() + 1] = nullptr;
return executeImpl(path.data(), argv.data(), false);
}
int ShellCommand::tryWait()
{
wait_called = true;
int status = 0;
if (-1 == waitpid(pid, &status, 0))
throwFromErrno("Cannot waitpid", ErrorCodes::CANNOT_WAITPID);
if (WIFEXITED(status))
return WEXITSTATUS(status);
if (WIFSIGNALED(status))
throw Exception("Child process was terminated by signal " + toString(WTERMSIG(status)), ErrorCodes::CHILD_WAS_NOT_EXITED_NORMALLY);
if (WIFSTOPPED(status))
throw Exception("Child process was stopped by signal " + toString(WSTOPSIG(status)), ErrorCodes::CHILD_WAS_NOT_EXITED_NORMALLY);
throw Exception("Child process was not exited normally by unknown reason", ErrorCodes::CHILD_WAS_NOT_EXITED_NORMALLY);
}
void ShellCommand::wait()
{
int retcode = tryWait();
if (retcode != EXIT_SUCCESS)
{
switch (retcode)
{
case int(ReturnCodes::CANNOT_DUP_STDIN):
throw Exception("Cannot dup2 stdin of child process", ErrorCodes::CANNOT_CREATE_CHILD_PROCESS);
case int(ReturnCodes::CANNOT_DUP_STDOUT):
throw Exception("Cannot dup2 stdout of child process", ErrorCodes::CANNOT_CREATE_CHILD_PROCESS);
case int(ReturnCodes::CANNOT_DUP_STDERR):
throw Exception("Cannot dup2 stderr of child process", ErrorCodes::CANNOT_CREATE_CHILD_PROCESS);
case int(ReturnCodes::CANNOT_EXEC):
throw Exception("Cannot execv in child process", ErrorCodes::CANNOT_CREATE_CHILD_PROCESS);
default:
throw Exception("Child process was exited with return code " + toString(retcode), ErrorCodes::CHILD_WAS_NOT_EXITED_NORMALLY);
}
}
}
}