2020-11-16 19:32:50 +03:00
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module os
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fn (mut p Process) unix_spawn_process() int {
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mut pipeset := [6]int{}
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if p.use_stdio_ctl {
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C.pipe(&pipeset[0]) // pipe read end 0 <- 1 pipe write end
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C.pipe(&pipeset[2]) // pipe read end 2 <- 3 pipe write end
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C.pipe(&pipeset[4]) // pipe read end 4 <- 5 pipe write end
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}
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pid := fork()
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if pid != 0 {
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// This is the parent process after the fork.
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// NB: pid contains the process ID of the child process
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if p.use_stdio_ctl {
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p.stdio_fd[0] = pipeset[1] // store the write end of child's in
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p.stdio_fd[1] = pipeset[2] // store the read end of child's out
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p.stdio_fd[2] = pipeset[4] // store the read end of child's err
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// close the rest of the pipe fds, the parent does not need them
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fd_close(pipeset[0])
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fd_close(pipeset[3])
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fd_close(pipeset[5])
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}
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return pid
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}
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//
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// Here, we are in the child process.
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// It still shares file descriptors with the parent process,
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// but it is otherwise independant and can do stuff *without*
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// affecting the parent process.
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if p.use_stdio_ctl {
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// Redirect the child standart in/out/err to the pipes that
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// were created in the parent.
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// Close the parent's pipe fds, the child do not need them:
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fd_close(pipeset[1])
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fd_close(pipeset[2])
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fd_close(pipeset[4])
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// redirect the pipe fds to the child's in/out/err fds:
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C.dup2(pipeset[0], 0)
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C.dup2(pipeset[3], 1)
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C.dup2(pipeset[5], 2)
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// close the pipe fdsx after the redirection
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fd_close(pipeset[0])
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fd_close(pipeset[3])
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fd_close(pipeset[5])
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}
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2020-12-30 18:57:01 +03:00
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execve(p.filename, p.args, p.env) or {
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eprintln(err)
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exit(1)
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2020-11-16 19:32:50 +03:00
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}
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return 0
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}
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fn (mut p Process) unix_stop_process() {
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C.kill(p.pid, C.SIGSTOP)
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}
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fn (mut p Process) unix_resume_process() {
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C.kill(p.pid, C.SIGCONT)
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}
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fn (mut p Process) unix_kill_process() {
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C.kill(p.pid, C.SIGKILL)
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}
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fn (mut p Process) unix_wait() {
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cstatus := 0
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ret := C.waitpid(p.pid, &cstatus, 0)
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if ret == -1 {
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p.err = posix_get_error_msg(C.errno)
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return
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}
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pret, is_signaled := posix_wait4_to_exit_status(cstatus)
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if is_signaled {
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p.status = .aborted
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p.err = 'Terminated by signal ${ret:2d} (${sigint_to_signal_name(pret)})'
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} else {
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p.status = .exited
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}
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p.code = pret
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}
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fn (mut p Process) unix_is_alive() bool {
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cstatus := 0
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ret := C.waitpid(p.pid, &cstatus, C.WNOHANG)
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if ret == -1 {
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p.err = posix_get_error_msg(C.errno)
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return false
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}
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if ret == 0 {
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return true
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}
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pret, is_signaled := posix_wait4_to_exit_status(cstatus)
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if is_signaled {
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p.status = .aborted
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p.err = 'Terminated by signal ${ret:2d} (${sigint_to_signal_name(pret)})'
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} else {
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p.status = .exited
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}
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p.code = pret
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return false
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}
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// these are here to make v_win.c/v.c generation work in all cases:
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fn (mut p Process) win_spawn_process() int {
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return 0
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}
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fn (mut p Process) win_stop_process() {
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}
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fn (mut p Process) win_resume_process() {
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}
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fn (mut p Process) win_kill_process() {
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}
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fn (mut p Process) win_wait() {
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}
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fn (mut p Process) win_is_alive() bool {
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return false
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}
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