// // Automated Testing Framework (atf) // // Copyright (c) 2008 The NetBSD Foundation, Inc. // All rights reserved. // // 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 NETBSD FOUNDATION, INC. 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 FOUNDATION 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. // extern "C" { #include #include #include #include } #include #include #include #include #include #include "exceptions.hpp" #include "text.hpp" #include "process.hpp" namespace detail = tools::process::detail; namespace impl = tools::process; #define IMPL_NAME "tools::process" // ------------------------------------------------------------------------ // Auxiliary functions. // ------------------------------------------------------------------------ template< class C > tools::auto_array< const char* > collection_to_argv(const C& c) { tools::auto_array< const char* > argv(new const char*[c.size() + 1]); std::size_t pos = 0; for (typename C::const_iterator iter = c.begin(); iter != c.end(); iter++) { argv[pos] = (*iter).c_str(); pos++; } assert(pos == c.size()); argv[pos] = NULL; return argv; } template< class C > C argv_to_collection(const char* const* argv) { C c; for (const char* const* iter = argv; *iter != NULL; iter++) c.push_back(std::string(*iter)); return c; } static void safe_dup(const int oldfd, const int newfd) { if (oldfd != newfd) { if (dup2(oldfd, newfd) == -1) { throw tools::system_error(IMPL_NAME "::safe_dup", "Could not allocate file descriptor", errno); } else { ::close(oldfd); } } } static int const_execvp(const char *file, const char *const *argv) { return ::execvp(file, const_cast(argv)); #undef UNCONST } void detail::do_exec(void *v) { struct exec_args *ea = reinterpret_cast(v); if (ea->m_prehook != NULL) ea->m_prehook(); const int ret = const_execvp(ea->m_prog.c_str(), ea->m_argv.exec_argv()); const int errnocopy = errno; assert(ret == -1); std::cerr << "exec(" << ea->m_prog.str() << ") failed: " << std::strerror(errnocopy) << "\n"; std::exit(EXIT_FAILURE); } // ------------------------------------------------------------------------ // The "argv_array" type. // ------------------------------------------------------------------------ impl::argv_array::argv_array(void) : m_exec_argv(collection_to_argv(m_args)) { } impl::argv_array::argv_array(const char* arg1, ...) { m_args.push_back(arg1); { va_list ap; const char* nextarg; va_start(ap, arg1); while ((nextarg = va_arg(ap, const char*)) != NULL) m_args.push_back(nextarg); va_end(ap); } ctor_init_exec_argv(); } impl::argv_array::argv_array(const char* const* ca) : m_args(argv_to_collection< args_vector >(ca)), m_exec_argv(collection_to_argv(m_args)) { } impl::argv_array::argv_array(const argv_array& a) : m_args(a.m_args), m_exec_argv(collection_to_argv(m_args)) { } void impl::argv_array::ctor_init_exec_argv(void) { m_exec_argv = collection_to_argv(m_args); } const char* const* impl::argv_array::exec_argv(void) const { return m_exec_argv.get(); } impl::argv_array::size_type impl::argv_array::size(void) const { return m_args.size(); } const char* impl::argv_array::operator[](int idx) const { return m_args[idx].c_str(); } impl::argv_array::const_iterator impl::argv_array::begin(void) const { return m_args.begin(); } impl::argv_array::const_iterator impl::argv_array::end(void) const { return m_args.end(); } impl::argv_array& impl::argv_array::operator=(const argv_array& a) { if (this != &a) { m_args = a.m_args; m_exec_argv = collection_to_argv(m_args); } return *this; } // ------------------------------------------------------------------------ // The "stream" types. // ------------------------------------------------------------------------ impl::stream_capture::stream_capture(void) { for (int i = 0; i < 2; i++) m_pipefds[i] = -1; } impl::stream_capture::~stream_capture(void) { for (int i = 0; i < 2; i++) if (m_pipefds[i] != -1) ::close(m_pipefds[i]); } void impl::stream_capture::prepare(void) { if (pipe(m_pipefds) == -1) throw system_error(IMPL_NAME "::stream_capture::prepare", "Failed to create pipe", errno); } int impl::stream_capture::connect_parent(void) { ::close(m_pipefds[1]); m_pipefds[1] = -1; const int fd = m_pipefds[0]; m_pipefds[0] = -1; return fd; } void impl::stream_capture::connect_child(const int fd) { ::close(m_pipefds[0]); m_pipefds[0] = -1; if (m_pipefds[1] != fd) { safe_dup(m_pipefds[1], fd); } m_pipefds[1] = -1; } impl::stream_connect::stream_connect(const int src_fd, const int tgt_fd) : m_src_fd(src_fd), m_tgt_fd(tgt_fd) { } void impl::stream_connect::prepare(void) { } int impl::stream_connect::connect_parent(void) { return -1; } void impl::stream_connect::connect_child(const int fd __attribute__((__unused__))) { safe_dup(m_tgt_fd, m_src_fd); } impl::stream_inherit::stream_inherit(void) { } void impl::stream_inherit::prepare(void) { } int impl::stream_inherit::connect_parent(void) { return -1; } void impl::stream_inherit::connect_child(const int fd __attribute__((__unused__))) { } impl::stream_redirect_fd::stream_redirect_fd(const int fd) : m_fd(fd) { } void impl::stream_redirect_fd::prepare(void) { } int impl::stream_redirect_fd::connect_parent(void) { return -1; } void impl::stream_redirect_fd::connect_child(const int fd) { safe_dup(m_fd, fd); } impl::stream_redirect_path::stream_redirect_path(const tools::fs::path& p) : m_path(p) { } void impl::stream_redirect_path::prepare(void) { } int impl::stream_redirect_path::connect_parent(void) { return -1; } void impl::stream_redirect_path::connect_child(const int fd) { const int aux = ::open(m_path.c_str(), O_WRONLY | O_CREAT | O_TRUNC, 0644); if (aux == -1) throw system_error(IMPL_NAME "::stream_redirect_path::connect_child", "Could not create " + m_path.str(), errno); else safe_dup(aux, fd); } // ------------------------------------------------------------------------ // The "status" type. // ------------------------------------------------------------------------ impl::status::status(int s) : m_status(s) { } impl::status::~status(void) { } std::string impl::status::str(void) const { int mutable_status = m_status; std::stringstream rv; if (WIFEXITED(mutable_status)) rv << "exit(" << WEXITSTATUS(mutable_status); else if (WIFSTOPPED(mutable_status)) rv << "stopped(" << WSTOPSIG(mutable_status); else if (WIFSIGNALED(mutable_status)) rv << "terminated(" << WTERMSIG(mutable_status); if (WCOREDUMP(mutable_status)) rv << "/core)"; else rv << ")"; return rv.str(); } bool impl::status::exited(void) const { int mutable_status = m_status; return WIFEXITED(mutable_status); } int impl::status::exitstatus(void) const { assert(exited()); int mutable_status = m_status; return WEXITSTATUS(mutable_status); } bool impl::status::signaled(void) const { int mutable_status = m_status; return WIFSIGNALED(mutable_status); } int impl::status::termsig(void) const { assert(signaled()); int mutable_status = m_status; return WTERMSIG(mutable_status); } bool impl::status::coredump(void) const { assert(signaled()); int mutable_status = m_status; return WCOREDUMP(mutable_status); } // ------------------------------------------------------------------------ // The "child" type. // ------------------------------------------------------------------------ impl::child::child(const pid_t pid_arg, const int stdout_fd_arg, const int stderr_fd_arg) : m_pid(pid_arg), m_stdout(stdout_fd_arg), m_stderr(stderr_fd_arg), m_waited(false) { } impl::child::~child(void) { if (!m_waited) { ::kill(m_pid, SIGTERM); (void)wait(); if (m_stdout != -1) { ::close(m_stdout); m_stdout = -1; } if (m_stderr != -1) { ::close(m_stderr); m_stderr = -1; } } } impl::status impl::child::wait(void) { int s; if (::waitpid(m_pid, &s, 0) == -1) throw system_error(IMPL_NAME "::child::wait", "Failed waiting for " "process " + text::to_string(m_pid), errno); if (m_stdout != -1) { ::close(m_stdout); m_stdout = -1; } if (m_stderr != -1) { ::close(m_stderr); m_stderr = -1; } m_waited = true; return status(s); } pid_t impl::child::pid(void) const { return m_pid; } int impl::child::stdout_fd(void) { return m_stdout; } int impl::child::stderr_fd(void) { return m_stderr; } // ------------------------------------------------------------------------ // Free functions. // ------------------------------------------------------------------------ void detail::flush_streams(void) { // This is a weird hack to ensure that the output of the parent process // is flushed before executing a child which prevents, for example, the // output of the atf-run hooks to appear before the output of atf-run // itself. // // TODO: This should only be executed when inheriting the stdout or // stderr file descriptors. However, the flushing is specific to the // iostreams, so we cannot do it from the C library where all the process // logic is performed. Come up with a better design. std::cout.flush(); std::cerr.flush(); }