| @node Job Control, Name Service Switch, Processes, Top |
| @c %MENU% All about process groups and sessions |
| @chapter Job Control |
| |
| @cindex process groups |
| @cindex job control |
| @cindex job |
| @cindex session |
| @dfn{Job control} refers to the protocol for allowing a user to move |
| between multiple @dfn{process groups} (or @dfn{jobs}) within a single |
| @dfn{login session}. The job control facilities are set up so that |
| appropriate behavior for most programs happens automatically and they |
| need not do anything special about job control. So you can probably |
| ignore the material in this chapter unless you are writing a shell or |
| login program. |
| |
| You need to be familiar with concepts relating to process creation |
| (@pxref{Process Creation Concepts}) and signal handling (@pxref{Signal |
| Handling}) in order to understand this material presented in this |
| chapter. |
| |
| @menu |
| * Concepts of Job Control:: Jobs can be controlled by a shell. |
| * Job Control is Optional:: Not all POSIX systems support job control. |
| * Controlling Terminal:: How a process gets its controlling terminal. |
| * Access to the Terminal:: How processes share the controlling terminal. |
| * Orphaned Process Groups:: Jobs left after the user logs out. |
| * Implementing a Shell:: What a shell must do to implement job control. |
| * Functions for Job Control:: Functions to control process groups. |
| @end menu |
| |
| @node Concepts of Job Control, Job Control is Optional, , Job Control |
| @section Concepts of Job Control |
| |
| @cindex shell |
| The fundamental purpose of an interactive shell is to read |
| commands from the user's terminal and create processes to execute the |
| programs specified by those commands. It can do this using the |
| @code{fork} (@pxref{Creating a Process}) and @code{exec} |
| (@pxref{Executing a File}) functions. |
| |
| A single command may run just one process---but often one command uses |
| several processes. If you use the @samp{|} operator in a shell command, |
| you explicitly request several programs in their own processes. But |
| even if you run just one program, it can use multiple processes |
| internally. For example, a single compilation command such as @samp{cc |
| -c foo.c} typically uses four processes (though normally only two at any |
| given time). If you run @code{make}, its job is to run other programs |
| in separate processes. |
| |
| The processes belonging to a single command are called a @dfn{process |
| group} or @dfn{job}. This is so that you can operate on all of them at |
| once. For example, typing @kbd{C-c} sends the signal @code{SIGINT} to |
| terminate all the processes in the foreground process group. |
| |
| @cindex session |
| A @dfn{session} is a larger group of processes. Normally all the |
| processes that stem from a single login belong to the same session. |
| |
| Every process belongs to a process group. When a process is created, it |
| becomes a member of the same process group and session as its parent |
| process. You can put it in another process group using the |
| @code{setpgid} function, provided the process group belongs to the same |
| session. |
| |
| @cindex session leader |
| The only way to put a process in a different session is to make it the |
| initial process of a new session, or a @dfn{session leader}, using the |
| @code{setsid} function. This also puts the session leader into a new |
| process group, and you can't move it out of that process group again. |
| |
| Usually, new sessions are created by the system login program, and the |
| session leader is the process running the user's login shell. |
| |
| @cindex controlling terminal |
| A shell that supports job control must arrange to control which job can |
| use the terminal at any time. Otherwise there might be multiple jobs |
| trying to read from the terminal at once, and confusion about which |
| process should receive the input typed by the user. To prevent this, |
| the shell must cooperate with the terminal driver using the protocol |
| described in this chapter. |
| |
| @cindex foreground job |
| @cindex background job |
| The shell can give unlimited access to the controlling terminal to only |
| one process group at a time. This is called the @dfn{foreground job} on |
| that controlling terminal. Other process groups managed by the shell |
| that are executing without such access to the terminal are called |
| @dfn{background jobs}. |
| |
| @cindex stopped job |
| If a background job needs to read from its controlling |
| terminal, it is @dfn{stopped} by the terminal driver; if the |
| @code{TOSTOP} mode is set, likewise for writing. The user can stop |
| a foreground job by typing the SUSP character (@pxref{Special |
| Characters}) and a program can stop any job by sending it a |
| @code{SIGSTOP} signal. It's the responsibility of the shell to notice |
| when jobs stop, to notify the user about them, and to provide mechanisms |
| for allowing the user to interactively continue stopped jobs and switch |
| jobs between foreground and background. |
| |
| @xref{Access to the Terminal}, for more information about I/O to the |
| controlling terminal, |
| |
| @node Job Control is Optional, Controlling Terminal, Concepts of Job Control , Job Control |
| @section Job Control is Optional |
| @cindex job control is optional |
| |
| Not all operating systems support job control. The GNU system does |
| support job control, but if you are using the GNU library on some other |
| system, that system may not support job control itself. |
| |
| You can use the @code{_POSIX_JOB_CONTROL} macro to test at compile-time |
| whether the system supports job control. @xref{System Options}. |
| |
| If job control is not supported, then there can be only one process |
| group per session, which behaves as if it were always in the foreground. |
| The functions for creating additional process groups simply fail with |
| the error code @code{ENOSYS}. |
| |
| The macros naming the various job control signals (@pxref{Job Control |
| Signals}) are defined even if job control is not supported. However, |
| the system never generates these signals, and attempts to send a job |
| control signal or examine or specify their actions report errors or do |
| nothing. |
| |
| |
| @node Controlling Terminal, Access to the Terminal, Job Control is Optional, Job Control |
| @section Controlling Terminal of a Process |
| |
| One of the attributes of a process is its controlling terminal. Child |
| processes created with @code{fork} inherit the controlling terminal from |
| their parent process. In this way, all the processes in a session |
| inherit the controlling terminal from the session leader. A session |
| leader that has control of a terminal is called the @dfn{controlling |
| process} of that terminal. |
| |
| @cindex controlling process |
| You generally do not need to worry about the exact mechanism used to |
| allocate a controlling terminal to a session, since it is done for you |
| by the system when you log in. |
| @c ??? How does GNU system let a process get a ctl terminal. |
| |
| An individual process disconnects from its controlling terminal when it |
| calls @code{setsid} to become the leader of a new session. |
| @xref{Process Group Functions}. |
| |
| @c !!! explain how it gets a new one (by opening any terminal) |
| @c ??? How you get a controlling terminal is system-dependent. |
| @c We should document how this will work in the GNU system when it is decided. |
| @c What Unix does is not clean and I don't think GNU should use that. |
| |
| @node Access to the Terminal, Orphaned Process Groups, Controlling Terminal, Job Control |
| @section Access to the Controlling Terminal |
| @cindex controlling terminal, access to |
| |
| Processes in the foreground job of a controlling terminal have |
| unrestricted access to that terminal; background processes do not. This |
| section describes in more detail what happens when a process in a |
| background job tries to access its controlling terminal. |
| |
| @cindex @code{SIGTTIN}, from background job |
| When a process in a background job tries to read from its controlling |
| terminal, the process group is usually sent a @code{SIGTTIN} signal. |
| This normally causes all of the processes in that group to stop (unless |
| they handle the signal and don't stop themselves). However, if the |
| reading process is ignoring or blocking this signal, then @code{read} |
| fails with an @code{EIO} error instead. |
| |
| @cindex @code{SIGTTOU}, from background job |
| Similarly, when a process in a background job tries to write to its |
| controlling terminal, the default behavior is to send a @code{SIGTTOU} |
| signal to the process group. However, the behavior is modified by the |
| @code{TOSTOP} bit of the local modes flags (@pxref{Local Modes}). If |
| this bit is not set (which is the default), then writing to the |
| controlling terminal is always permitted without sending a signal. |
| Writing is also permitted if the @code{SIGTTOU} signal is being ignored |
| or blocked by the writing process. |
| |
| Most other terminal operations that a program can do are treated as |
| reading or as writing. (The description of each operation should say |
| which.) |
| |
| For more information about the primitive @code{read} and @code{write} |
| functions, see @ref{I/O Primitives}. |
| |
| |
| @node Orphaned Process Groups, Implementing a Shell, Access to the Terminal, Job Control |
| @section Orphaned Process Groups |
| @cindex orphaned process group |
| |
| When a controlling process terminates, its terminal becomes free and a |
| new session can be established on it. (In fact, another user could log |
| in on the terminal.) This could cause a problem if any processes from |
| the old session are still trying to use that terminal. |
| |
| To prevent problems, process groups that continue running even after the |
| session leader has terminated are marked as @dfn{orphaned process |
| groups}. |
| |
| When a process group becomes an orphan, its processes are sent a |
| @code{SIGHUP} signal. Ordinarily, this causes the processes to |
| terminate. However, if a program ignores this signal or establishes a |
| handler for it (@pxref{Signal Handling}), it can continue running as in |
| the orphan process group even after its controlling process terminates; |
| but it still cannot access the terminal any more. |
| |
| @node Implementing a Shell, Functions for Job Control, Orphaned Process Groups, Job Control |
| @section Implementing a Job Control Shell |
| |
| This section describes what a shell must do to implement job control, by |
| presenting an extensive sample program to illustrate the concepts |
| involved. |
| |
| @iftex |
| @itemize @bullet |
| @item |
| @ref{Data Structures}, introduces the example and presents |
| its primary data structures. |
| |
| @item |
| @ref{Initializing the Shell}, discusses actions which the shell must |
| perform to prepare for job control. |
| |
| @item |
| @ref{Launching Jobs}, includes information about how to create jobs |
| to execute commands. |
| |
| @item |
| @ref{Foreground and Background}, discusses what the shell should |
| do differently when launching a job in the foreground as opposed to |
| a background job. |
| |
| @item |
| @ref{Stopped and Terminated Jobs}, discusses reporting of job status |
| back to the shell. |
| |
| @item |
| @ref{Continuing Stopped Jobs}, tells you how to continue jobs that |
| have been stopped. |
| |
| @item |
| @ref{Missing Pieces}, discusses other parts of the shell. |
| @end itemize |
| @end iftex |
| |
| @menu |
| * Data Structures:: Introduction to the sample shell. |
| * Initializing the Shell:: What the shell must do to take |
| responsibility for job control. |
| * Launching Jobs:: Creating jobs to execute commands. |
| * Foreground and Background:: Putting a job in foreground of background. |
| * Stopped and Terminated Jobs:: Reporting job status. |
| * Continuing Stopped Jobs:: How to continue a stopped job in |
| the foreground or background. |
| * Missing Pieces:: Other parts of the shell. |
| @end menu |
| |
| @node Data Structures, Initializing the Shell, , Implementing a Shell |
| @subsection Data Structures for the Shell |
| |
| All of the program examples included in this chapter are part of |
| a simple shell program. This section presents data structures |
| and utility functions which are used throughout the example. |
| |
| The sample shell deals mainly with two data structures. The |
| @code{job} type contains information about a job, which is a |
| set of subprocesses linked together with pipes. The @code{process} type |
| holds information about a single subprocess. Here are the relevant |
| data structure declarations: |
| |
| @smallexample |
| @group |
| /* @r{A process is a single process.} */ |
| typedef struct process |
| @{ |
| struct process *next; /* @r{next process in pipeline} */ |
| char **argv; /* @r{for exec} */ |
| pid_t pid; /* @r{process ID} */ |
| char completed; /* @r{true if process has completed} */ |
| char stopped; /* @r{true if process has stopped} */ |
| int status; /* @r{reported status value} */ |
| @} process; |
| @end group |
| |
| @group |
| /* @r{A job is a pipeline of processes.} */ |
| typedef struct job |
| @{ |
| struct job *next; /* @r{next active job} */ |
| char *command; /* @r{command line, used for messages} */ |
| process *first_process; /* @r{list of processes in this job} */ |
| pid_t pgid; /* @r{process group ID} */ |
| char notified; /* @r{true if user told about stopped job} */ |
| struct termios tmodes; /* @r{saved terminal modes} */ |
| int stdin, stdout, stderr; /* @r{standard i/o channels} */ |
| @} job; |
| |
| /* @r{The active jobs are linked into a list. This is its head.} */ |
| job *first_job = NULL; |
| @end group |
| @end smallexample |
| |
| Here are some utility functions that are used for operating on @code{job} |
| objects. |
| |
| @smallexample |
| @group |
| /* @r{Find the active job with the indicated @var{pgid}.} */ |
| job * |
| find_job (pid_t pgid) |
| @{ |
| job *j; |
| |
| for (j = first_job; j; j = j->next) |
| if (j->pgid == pgid) |
| return j; |
| return NULL; |
| @} |
| @end group |
| |
| @group |
| /* @r{Return true if all processes in the job have stopped or completed.} */ |
| int |
| job_is_stopped (job *j) |
| @{ |
| process *p; |
| |
| for (p = j->first_process; p; p = p->next) |
| if (!p->completed && !p->stopped) |
| return 0; |
| return 1; |
| @} |
| @end group |
| |
| @group |
| /* @r{Return true if all processes in the job have completed.} */ |
| int |
| job_is_completed (job *j) |
| @{ |
| process *p; |
| |
| for (p = j->first_process; p; p = p->next) |
| if (!p->completed) |
| return 0; |
| return 1; |
| @} |
| @end group |
| @end smallexample |
| |
| |
| @node Initializing the Shell, Launching Jobs, Data Structures, Implementing a Shell |
| @subsection Initializing the Shell |
| @cindex job control, enabling |
| @cindex subshell |
| |
| When a shell program that normally performs job control is started, it |
| has to be careful in case it has been invoked from another shell that is |
| already doing its own job control. |
| |
| A subshell that runs interactively has to ensure that it has been placed |
| in the foreground by its parent shell before it can enable job control |
| itself. It does this by getting its initial process group ID with the |
| @code{getpgrp} function, and comparing it to the process group ID of the |
| current foreground job associated with its controlling terminal (which |
| can be retrieved using the @code{tcgetpgrp} function). |
| |
| If the subshell is not running as a foreground job, it must stop itself |
| by sending a @code{SIGTTIN} signal to its own process group. It may not |
| arbitrarily put itself into the foreground; it must wait for the user to |
| tell the parent shell to do this. If the subshell is continued again, |
| it should repeat the check and stop itself again if it is still not in |
| the foreground. |
| |
| @cindex job control, enabling |
| Once the subshell has been placed into the foreground by its parent |
| shell, it can enable its own job control. It does this by calling |
| @code{setpgid} to put itself into its own process group, and then |
| calling @code{tcsetpgrp} to place this process group into the |
| foreground. |
| |
| When a shell enables job control, it should set itself to ignore all the |
| job control stop signals so that it doesn't accidentally stop itself. |
| You can do this by setting the action for all the stop signals to |
| @code{SIG_IGN}. |
| |
| A subshell that runs non-interactively cannot and should not support job |
| control. It must leave all processes it creates in the same process |
| group as the shell itself; this allows the non-interactive shell and its |
| child processes to be treated as a single job by the parent shell. This |
| is easy to do---just don't use any of the job control primitives---but |
| you must remember to make the shell do it. |
| |
| |
| Here is the initialization code for the sample shell that shows how to |
| do all of this. |
| |
| @smallexample |
| /* @r{Keep track of attributes of the shell.} */ |
| |
| #include <sys/types.h> |
| #include <termios.h> |
| #include <unistd.h> |
| |
| pid_t shell_pgid; |
| struct termios shell_tmodes; |
| int shell_terminal; |
| int shell_is_interactive; |
| |
| |
| /* @r{Make sure the shell is running interactively as the foreground job} |
| @r{before proceeding.} */ |
| |
| void |
| init_shell () |
| @{ |
| |
| /* @r{See if we are running interactively.} */ |
| shell_terminal = STDIN_FILENO; |
| shell_is_interactive = isatty (shell_terminal); |
| |
| if (shell_is_interactive) |
| @{ |
| /* @r{Loop until we are in the foreground.} */ |
| while (tcgetpgrp (shell_terminal) != (shell_pgid = getpgrp ())) |
| kill (- shell_pgid, SIGTTIN); |
| |
| /* @r{Ignore interactive and job-control signals.} */ |
| signal (SIGINT, SIG_IGN); |
| signal (SIGQUIT, SIG_IGN); |
| signal (SIGTSTP, SIG_IGN); |
| signal (SIGTTIN, SIG_IGN); |
| signal (SIGTTOU, SIG_IGN); |
| signal (SIGCHLD, SIG_IGN); |
| |
| /* @r{Put ourselves in our own process group.} */ |
| shell_pgid = getpid (); |
| if (setpgid (shell_pgid, shell_pgid) < 0) |
| @{ |
| perror ("Couldn't put the shell in its own process group"); |
| exit (1); |
| @} |
| |
| /* @r{Grab control of the terminal.} */ |
| tcsetpgrp (shell_terminal, shell_pgid); |
| |
| /* @r{Save default terminal attributes for shell.} */ |
| tcgetattr (shell_terminal, &shell_tmodes); |
| @} |
| @} |
| @end smallexample |
| |
| |
| @node Launching Jobs, Foreground and Background, Initializing the Shell, Implementing a Shell |
| @subsection Launching Jobs |
| @cindex launching jobs |
| |
| Once the shell has taken responsibility for performing job control on |
| its controlling terminal, it can launch jobs in response to commands |
| typed by the user. |
| |
| To create the processes in a process group, you use the same @code{fork} |
| and @code{exec} functions described in @ref{Process Creation Concepts}. |
| Since there are multiple child processes involved, though, things are a |
| little more complicated and you must be careful to do things in the |
| right order. Otherwise, nasty race conditions can result. |
| |
| You have two choices for how to structure the tree of parent-child |
| relationships among the processes. You can either make all the |
| processes in the process group be children of the shell process, or you |
| can make one process in group be the ancestor of all the other processes |
| in that group. The sample shell program presented in this chapter uses |
| the first approach because it makes bookkeeping somewhat simpler. |
| |
| @cindex process group leader |
| @cindex process group ID |
| As each process is forked, it should put itself in the new process group |
| by calling @code{setpgid}; see @ref{Process Group Functions}. The first |
| process in the new group becomes its @dfn{process group leader}, and its |
| process ID becomes the @dfn{process group ID} for the group. |
| |
| @cindex race conditions, relating to job control |
| The shell should also call @code{setpgid} to put each of its child |
| processes into the new process group. This is because there is a |
| potential timing problem: each child process must be put in the process |
| group before it begins executing a new program, and the shell depends on |
| having all the child processes in the group before it continues |
| executing. If both the child processes and the shell call |
| @code{setpgid}, this ensures that the right things happen no matter which |
| process gets to it first. |
| |
| If the job is being launched as a foreground job, the new process group |
| also needs to be put into the foreground on the controlling terminal |
| using @code{tcsetpgrp}. Again, this should be done by the shell as well |
| as by each of its child processes, to avoid race conditions. |
| |
| The next thing each child process should do is to reset its signal |
| actions. |
| |
| During initialization, the shell process set itself to ignore job |
| control signals; see @ref{Initializing the Shell}. As a result, any child |
| processes it creates also ignore these signals by inheritance. This is |
| definitely undesirable, so each child process should explicitly set the |
| actions for these signals back to @code{SIG_DFL} just after it is forked. |
| |
| Since shells follow this convention, applications can assume that they |
| inherit the correct handling of these signals from the parent process. |
| But every application has a responsibility not to mess up the handling |
| of stop signals. Applications that disable the normal interpretation of |
| the SUSP character should provide some other mechanism for the user to |
| stop the job. When the user invokes this mechanism, the program should |
| send a @code{SIGTSTP} signal to the process group of the process, not |
| just to the process itself. @xref{Signaling Another Process}. |
| |
| Finally, each child process should call @code{exec} in the normal way. |
| This is also the point at which redirection of the standard input and |
| output channels should be handled. @xref{Duplicating Descriptors}, |
| for an explanation of how to do this. |
| |
| Here is the function from the sample shell program that is responsible |
| for launching a program. The function is executed by each child process |
| immediately after it has been forked by the shell, and never returns. |
| |
| @smallexample |
| void |
| launch_process (process *p, pid_t pgid, |
| int infile, int outfile, int errfile, |
| int foreground) |
| @{ |
| pid_t pid; |
| |
| if (shell_is_interactive) |
| @{ |
| /* @r{Put the process into the process group and give the process group} |
| @r{the terminal, if appropriate.} |
| @r{This has to be done both by the shell and in the individual} |
| @r{child processes because of potential race conditions.} */ |
| pid = getpid (); |
| if (pgid == 0) pgid = pid; |
| setpgid (pid, pgid); |
| if (foreground) |
| tcsetpgrp (shell_terminal, pgid); |
| |
| /* @r{Set the handling for job control signals back to the default.} */ |
| signal (SIGINT, SIG_DFL); |
| signal (SIGQUIT, SIG_DFL); |
| signal (SIGTSTP, SIG_DFL); |
| signal (SIGTTIN, SIG_DFL); |
| signal (SIGTTOU, SIG_DFL); |
| signal (SIGCHLD, SIG_DFL); |
| @} |
| |
| /* @r{Set the standard input/output channels of the new process.} */ |
| if (infile != STDIN_FILENO) |
| @{ |
| dup2 (infile, STDIN_FILENO); |
| close (infile); |
| @} |
| if (outfile != STDOUT_FILENO) |
| @{ |
| dup2 (outfile, STDOUT_FILENO); |
| close (outfile); |
| @} |
| if (errfile != STDERR_FILENO) |
| @{ |
| dup2 (errfile, STDERR_FILENO); |
| close (errfile); |
| @} |
| |
| /* @r{Exec the new process. Make sure we exit.} */ |
| execvp (p->argv[0], p->argv); |
| perror ("execvp"); |
| exit (1); |
| @} |
| @end smallexample |
| |
| If the shell is not running interactively, this function does not do |
| anything with process groups or signals. Remember that a shell not |
| performing job control must keep all of its subprocesses in the same |
| process group as the shell itself. |
| |
| Next, here is the function that actually launches a complete job. |
| After creating the child processes, this function calls some other |
| functions to put the newly created job into the foreground or background; |
| these are discussed in @ref{Foreground and Background}. |
| |
| @smallexample |
| void |
| launch_job (job *j, int foreground) |
| @{ |
| process *p; |
| pid_t pid; |
| int mypipe[2], infile, outfile; |
| |
| infile = j->stdin; |
| for (p = j->first_process; p; p = p->next) |
| @{ |
| /* @r{Set up pipes, if necessary.} */ |
| if (p->next) |
| @{ |
| if (pipe (mypipe) < 0) |
| @{ |
| perror ("pipe"); |
| exit (1); |
| @} |
| outfile = mypipe[1]; |
| @} |
| else |
| outfile = j->stdout; |
| |
| /* @r{Fork the child processes.} */ |
| pid = fork (); |
| if (pid == 0) |
| /* @r{This is the child process.} */ |
| launch_process (p, j->pgid, infile, |
| outfile, j->stderr, foreground); |
| else if (pid < 0) |
| @{ |
| /* @r{The fork failed.} */ |
| perror ("fork"); |
| exit (1); |
| @} |
| else |
| @{ |
| /* @r{This is the parent process.} */ |
| p->pid = pid; |
| if (shell_is_interactive) |
| @{ |
| if (!j->pgid) |
| j->pgid = pid; |
| setpgid (pid, j->pgid); |
| @} |
| @} |
| |
| /* @r{Clean up after pipes.} */ |
| if (infile != j->stdin) |
| close (infile); |
| if (outfile != j->stdout) |
| close (outfile); |
| infile = mypipe[0]; |
| @} |
| |
| format_job_info (j, "launched"); |
| |
| if (!shell_is_interactive) |
| wait_for_job (j); |
| else if (foreground) |
| put_job_in_foreground (j, 0); |
| else |
| put_job_in_background (j, 0); |
| @} |
| @end smallexample |
| |
| |
| @node Foreground and Background, Stopped and Terminated Jobs, Launching Jobs, Implementing a Shell |
| @subsection Foreground and Background |
| |
| Now let's consider what actions must be taken by the shell when it |
| launches a job into the foreground, and how this differs from what |
| must be done when a background job is launched. |
| |
| @cindex foreground job, launching |
| When a foreground job is launched, the shell must first give it access |
| to the controlling terminal by calling @code{tcsetpgrp}. Then, the |
| shell should wait for processes in that process group to terminate or |
| stop. This is discussed in more detail in @ref{Stopped and Terminated |
| Jobs}. |
| |
| When all of the processes in the group have either completed or stopped, |
| the shell should regain control of the terminal for its own process |
| group by calling @code{tcsetpgrp} again. Since stop signals caused by |
| I/O from a background process or a SUSP character typed by the user |
| are sent to the process group, normally all the processes in the job |
| stop together. |
| |
| The foreground job may have left the terminal in a strange state, so the |
| shell should restore its own saved terminal modes before continuing. In |
| case the job is merely stopped, the shell should first save the current |
| terminal modes so that it can restore them later if the job is |
| continued. The functions for dealing with terminal modes are |
| @code{tcgetattr} and @code{tcsetattr}; these are described in |
| @ref{Terminal Modes}. |
| |
| Here is the sample shell's function for doing all of this. |
| |
| @smallexample |
| @group |
| /* @r{Put job @var{j} in the foreground. If @var{cont} is nonzero,} |
| @r{restore the saved terminal modes and send the process group a} |
| @r{@code{SIGCONT} signal to wake it up before we block.} */ |
| |
| void |
| put_job_in_foreground (job *j, int cont) |
| @{ |
| /* @r{Put the job into the foreground.} */ |
| tcsetpgrp (shell_terminal, j->pgid); |
| @end group |
| |
| @group |
| /* @r{Send the job a continue signal, if necessary.} */ |
| if (cont) |
| @{ |
| tcsetattr (shell_terminal, TCSADRAIN, &j->tmodes); |
| if (kill (- j->pgid, SIGCONT) < 0) |
| perror ("kill (SIGCONT)"); |
| @} |
| @end group |
| |
| /* @r{Wait for it to report.} */ |
| wait_for_job (j); |
| |
| /* @r{Put the shell back in the foreground.} */ |
| tcsetpgrp (shell_terminal, shell_pgid); |
| |
| @group |
| /* @r{Restore the shell's terminal modes.} */ |
| tcgetattr (shell_terminal, &j->tmodes); |
| tcsetattr (shell_terminal, TCSADRAIN, &shell_tmodes); |
| @} |
| @end group |
| @end smallexample |
| |
| @cindex background job, launching |
| If the process group is launched as a background job, the shell should |
| remain in the foreground itself and continue to read commands from |
| the terminal. |
| |
| In the sample shell, there is not much that needs to be done to put |
| a job into the background. Here is the function it uses: |
| |
| @smallexample |
| /* @r{Put a job in the background. If the cont argument is true, send} |
| @r{the process group a @code{SIGCONT} signal to wake it up.} */ |
| |
| void |
| put_job_in_background (job *j, int cont) |
| @{ |
| /* @r{Send the job a continue signal, if necessary.} */ |
| if (cont) |
| if (kill (-j->pgid, SIGCONT) < 0) |
| perror ("kill (SIGCONT)"); |
| @} |
| @end smallexample |
| |
| |
| @node Stopped and Terminated Jobs, Continuing Stopped Jobs, Foreground and Background, Implementing a Shell |
| @subsection Stopped and Terminated Jobs |
| |
| @cindex stopped jobs, detecting |
| @cindex terminated jobs, detecting |
| When a foreground process is launched, the shell must block until all of |
| the processes in that job have either terminated or stopped. It can do |
| this by calling the @code{waitpid} function; see @ref{Process |
| Completion}. Use the @code{WUNTRACED} option so that status is reported |
| for processes that stop as well as processes that terminate. |
| |
| The shell must also check on the status of background jobs so that it |
| can report terminated and stopped jobs to the user; this can be done by |
| calling @code{waitpid} with the @code{WNOHANG} option. A good place to |
| put a such a check for terminated and stopped jobs is just before |
| prompting for a new command. |
| |
| @cindex @code{SIGCHLD}, handling of |
| The shell can also receive asynchronous notification that there is |
| status information available for a child process by establishing a |
| handler for @code{SIGCHLD} signals. @xref{Signal Handling}. |
| |
| In the sample shell program, the @code{SIGCHLD} signal is normally |
| ignored. This is to avoid reentrancy problems involving the global data |
| structures the shell manipulates. But at specific times when the shell |
| is not using these data structures---such as when it is waiting for |
| input on the terminal---it makes sense to enable a handler for |
| @code{SIGCHLD}. The same function that is used to do the synchronous |
| status checks (@code{do_job_notification}, in this case) can also be |
| called from within this handler. |
| |
| Here are the parts of the sample shell program that deal with checking |
| the status of jobs and reporting the information to the user. |
| |
| @smallexample |
| @group |
| /* @r{Store the status of the process @var{pid} that was returned by waitpid.} |
| @r{Return 0 if all went well, nonzero otherwise.} */ |
| |
| int |
| mark_process_status (pid_t pid, int status) |
| @{ |
| job *j; |
| process *p; |
| @end group |
| |
| @group |
| if (pid > 0) |
| @{ |
| /* @r{Update the record for the process.} */ |
| for (j = first_job; j; j = j->next) |
| for (p = j->first_process; p; p = p->next) |
| if (p->pid == pid) |
| @{ |
| p->status = status; |
| if (WIFSTOPPED (status)) |
| p->stopped = 1; |
| else |
| @{ |
| p->completed = 1; |
| if (WIFSIGNALED (status)) |
| fprintf (stderr, "%d: Terminated by signal %d.\n", |
| (int) pid, WTERMSIG (p->status)); |
| @} |
| return 0; |
| @} |
| fprintf (stderr, "No child process %d.\n", pid); |
| return -1; |
| @} |
| @end group |
| @group |
| else if (pid == 0 || errno == ECHILD) |
| /* @r{No processes ready to report.} */ |
| return -1; |
| else @{ |
| /* @r{Other weird errors.} */ |
| perror ("waitpid"); |
| return -1; |
| @} |
| @} |
| @end group |
| |
| @group |
| /* @r{Check for processes that have status information available,} |
| @r{without blocking.} */ |
| |
| void |
| update_status (void) |
| @{ |
| int status; |
| pid_t pid; |
| |
| do |
| pid = waitpid (WAIT_ANY, &status, WUNTRACED|WNOHANG); |
| while (!mark_process_status (pid, status)); |
| @} |
| @end group |
| |
| @group |
| /* @r{Check for processes that have status information available,} |
| @r{blocking until all processes in the given job have reported.} */ |
| |
| void |
| wait_for_job (job *j) |
| @{ |
| int status; |
| pid_t pid; |
| |
| do |
| pid = waitpid (WAIT_ANY, &status, WUNTRACED); |
| while (!mark_process_status (pid, status) |
| && !job_is_stopped (j) |
| && !job_is_completed (j)); |
| @} |
| @end group |
| |
| @group |
| /* @r{Format information about job status for the user to look at.} */ |
| |
| void |
| format_job_info (job *j, const char *status) |
| @{ |
| fprintf (stderr, "%ld (%s): %s\n", (long)j->pgid, status, j->command); |
| @} |
| @end group |
| |
| @group |
| /* @r{Notify the user about stopped or terminated jobs.} |
| @r{Delete terminated jobs from the active job list.} */ |
| |
| void |
| do_job_notification (void) |
| @{ |
| job *j, *jlast, *jnext; |
| process *p; |
| |
| /* @r{Update status information for child processes.} */ |
| update_status (); |
| |
| jlast = NULL; |
| for (j = first_job; j; j = jnext) |
| @{ |
| jnext = j->next; |
| |
| /* @r{If all processes have completed, tell the user the job has} |
| @r{completed and delete it from the list of active jobs.} */ |
| if (job_is_completed (j)) @{ |
| format_job_info (j, "completed"); |
| if (jlast) |
| jlast->next = jnext; |
| else |
| first_job = jnext; |
| free_job (j); |
| @} |
| |
| /* @r{Notify the user about stopped jobs,} |
| @r{marking them so that we won't do this more than once.} */ |
| else if (job_is_stopped (j) && !j->notified) @{ |
| format_job_info (j, "stopped"); |
| j->notified = 1; |
| jlast = j; |
| @} |
| |
| /* @r{Don't say anything about jobs that are still running.} */ |
| else |
| jlast = j; |
| @} |
| @} |
| @end group |
| @end smallexample |
| |
| @node Continuing Stopped Jobs, Missing Pieces, Stopped and Terminated Jobs, Implementing a Shell |
| @subsection Continuing Stopped Jobs |
| |
| @cindex stopped jobs, continuing |
| The shell can continue a stopped job by sending a @code{SIGCONT} signal |
| to its process group. If the job is being continued in the foreground, |
| the shell should first invoke @code{tcsetpgrp} to give the job access to |
| the terminal, and restore the saved terminal settings. After continuing |
| a job in the foreground, the shell should wait for the job to stop or |
| complete, as if the job had just been launched in the foreground. |
| |
| The sample shell program handles both newly created and continued jobs |
| with the same pair of functions, @w{@code{put_job_in_foreground}} and |
| @w{@code{put_job_in_background}}. The definitions of these functions |
| were given in @ref{Foreground and Background}. When continuing a |
| stopped job, a nonzero value is passed as the @var{cont} argument to |
| ensure that the @code{SIGCONT} signal is sent and the terminal modes |
| reset, as appropriate. |
| |
| This leaves only a function for updating the shell's internal bookkeeping |
| about the job being continued: |
| |
| @smallexample |
| @group |
| /* @r{Mark a stopped job J as being running again.} */ |
| |
| void |
| mark_job_as_running (job *j) |
| @{ |
| Process *p; |
| |
| for (p = j->first_process; p; p = p->next) |
| p->stopped = 0; |
| j->notified = 0; |
| @} |
| @end group |
| |
| @group |
| /* @r{Continue the job J.} */ |
| |
| void |
| continue_job (job *j, int foreground) |
| @{ |
| mark_job_as_running (j); |
| if (foreground) |
| put_job_in_foreground (j, 1); |
| else |
| put_job_in_background (j, 1); |
| @} |
| @end group |
| @end smallexample |
| |
| @node Missing Pieces, , Continuing Stopped Jobs, Implementing a Shell |
| @subsection The Missing Pieces |
| |
| The code extracts for the sample shell included in this chapter are only |
| a part of the entire shell program. In particular, nothing at all has |
| been said about how @code{job} and @code{program} data structures are |
| allocated and initialized. |
| |
| Most real shells provide a complex user interface that has support for |
| a command language; variables; abbreviations, substitutions, and pattern |
| matching on file names; and the like. All of this is far too complicated |
| to explain here! Instead, we have concentrated on showing how to |
| implement the core process creation and job control functions that can |
| be called from such a shell. |
| |
| Here is a table summarizing the major entry points we have presented: |
| |
| @table @code |
| @item void init_shell (void) |
| Initialize the shell's internal state. @xref{Initializing the |
| Shell}. |
| |
| @item void launch_job (job *@var{j}, int @var{foreground}) |
| Launch the job @var{j} as either a foreground or background job. |
| @xref{Launching Jobs}. |
| |
| @item void do_job_notification (void) |
| Check for and report any jobs that have terminated or stopped. Can be |
| called synchronously or within a handler for @code{SIGCHLD} signals. |
| @xref{Stopped and Terminated Jobs}. |
| |
| @item void continue_job (job *@var{j}, int @var{foreground}) |
| Continue the job @var{j}. @xref{Continuing Stopped Jobs}. |
| @end table |
| |
| Of course, a real shell would also want to provide other functions for |
| managing jobs. For example, it would be useful to have commands to list |
| all active jobs or to send a signal (such as @code{SIGKILL}) to a job. |
| |
| |
| @node Functions for Job Control, , Implementing a Shell, Job Control |
| @section Functions for Job Control |
| @cindex process group functions |
| @cindex job control functions |
| |
| This section contains detailed descriptions of the functions relating |
| to job control. |
| |
| @menu |
| * Identifying the Terminal:: Determining the controlling terminal's name. |
| * Process Group Functions:: Functions for manipulating process groups. |
| * Terminal Access Functions:: Functions for controlling terminal access. |
| @end menu |
| |
| |
| @node Identifying the Terminal, Process Group Functions, , Functions for Job Control |
| @subsection Identifying the Controlling Terminal |
| @cindex controlling terminal, determining |
| |
| You can use the @code{ctermid} function to get a file name that you can |
| use to open the controlling terminal. In the GNU library, it returns |
| the same string all the time: @code{"/dev/tty"}. That is a special |
| ``magic'' file name that refers to the controlling terminal of the |
| current process (if it has one). To find the name of the specific |
| terminal device, use @code{ttyname}; @pxref{Is It a Terminal}. |
| |
| The function @code{ctermid} is declared in the header file |
| @file{stdio.h}. |
| @pindex stdio.h |
| |
| @comment stdio.h |
| @comment POSIX.1 |
| @deftypefun {char *} ctermid (char *@var{string}) |
| The @code{ctermid} function returns a string containing the file name of |
| the controlling terminal for the current process. If @var{string} is |
| not a null pointer, it should be an array that can hold at least |
| @code{L_ctermid} characters; the string is returned in this array. |
| Otherwise, a pointer to a string in a static area is returned, which |
| might get overwritten on subsequent calls to this function. |
| |
| An empty string is returned if the file name cannot be determined for |
| any reason. Even if a file name is returned, access to the file it |
| represents is not guaranteed. |
| @end deftypefun |
| |
| @comment stdio.h |
| @comment POSIX.1 |
| @deftypevr Macro int L_ctermid |
| The value of this macro is an integer constant expression that |
| represents the size of a string large enough to hold the file name |
| returned by @code{ctermid}. |
| @end deftypevr |
| |
| See also the @code{isatty} and @code{ttyname} functions, in |
| @ref{Is It a Terminal}. |
| |
| |
| @node Process Group Functions, Terminal Access Functions, Identifying the Terminal, Functions for Job Control |
| @subsection Process Group Functions |
| |
| Here are descriptions of the functions for manipulating process groups. |
| Your program should include the header files @file{sys/types.h} and |
| @file{unistd.h} to use these functions. |
| @pindex unistd.h |
| @pindex sys/types.h |
| |
| @comment unistd.h |
| @comment POSIX.1 |
| @deftypefun pid_t setsid (void) |
| The @code{setsid} function creates a new session. The calling process |
| becomes the session leader, and is put in a new process group whose |
| process group ID is the same as the process ID of that process. There |
| are initially no other processes in the new process group, and no other |
| process groups in the new session. |
| |
| This function also makes the calling process have no controlling terminal. |
| |
| The @code{setsid} function returns the new process group ID of the |
| calling process if successful. A return value of @code{-1} indicates an |
| error. The following @code{errno} error conditions are defined for this |
| function: |
| |
| @table @code |
| @item EPERM |
| The calling process is already a process group leader, or there is |
| already another process group around that has the same process group ID. |
| @end table |
| @end deftypefun |
| |
| @comment unistd.h |
| @comment SVID |
| @deftypefun pid_t getsid (pid_t @var{pid}) |
| |
| The @code{getsid} function returns the process group ID of the session |
| leader of the specified process. If a @var{pid} is @code{0}, the |
| process group ID of the session leader of the current process is |
| returned. |
| |
| In case of error @code{-1} is returned and @code{errno} is set. The |
| following @code{errno} error conditions are defined for this function: |
| |
| @table @code |
| @item ESRCH |
| There is no process with the given process ID @var{pid}. |
| @item EPERM |
| The calling process and the process specified by @var{pid} are in |
| different sessions, and the implementation doesn't allow to access the |
| process group ID of the session leader of the process with ID @var{pid} |
| from the calling process. |
| @end table |
| @end deftypefun |
| |
| The @code{getpgrp} function has two definitions: one derived from BSD |
| Unix, and one from the POSIX.1 standard. The feature test macros you |
| have selected (@pxref{Feature Test Macros}) determine which definition |
| you get. Specifically, you get the BSD version if you define |
| @code{_BSD_SOURCE}; otherwise, you get the POSIX version if you define |
| @code{_POSIX_SOURCE} or @code{_GNU_SOURCE}. Programs written for old |
| BSD systems will not include @file{unistd.h}, which defines |
| @code{getpgrp} specially under @code{_BSD_SOURCE}. You must link such |
| programs with the @code{-lbsd-compat} option to get the BSD definition.@refill |
| @pindex -lbsd-compat |
| @pindex bsd-compat |
| @cindex BSD compatibility library |
| |
| @comment unistd.h |
| @comment POSIX.1 |
| @deftypefn {POSIX.1 Function} pid_t getpgrp (void) |
| The POSIX.1 definition of @code{getpgrp} returns the process group ID of |
| the calling process. |
| @end deftypefn |
| |
| @comment unistd.h |
| @comment BSD |
| @deftypefn {BSD Function} pid_t getpgrp (pid_t @var{pid}) |
| The BSD definition of @code{getpgrp} returns the process group ID of the |
| process @var{pid}. You can supply a value of @code{0} for the @var{pid} |
| argument to get information about the calling process. |
| @end deftypefn |
| |
| @comment unistd.h |
| @comment SVID |
| @deftypefn {System V Function} int getpgid (pid_t @var{pid}) |
| |
| @code{getpgid} is the same as the BSD function @code{getpgrp}. It |
| returns the process group ID of the process @var{pid}. You can supply a |
| value of @code{0} for the @var{pid} argument to get information about |
| the calling process. |
| |
| In case of error @code{-1} is returned and @code{errno} is set. The |
| following @code{errno} error conditions are defined for this function: |
| |
| @table @code |
| @item ESRCH |
| There is no process with the given process ID @var{pid}. |
| The calling process and the process specified by @var{pid} are in |
| different sessions, and the implementation doesn't allow to access the |
| process group ID of the process with ID @var{pid} from the calling |
| process. |
| @end table |
| @end deftypefn |
| |
| @comment unistd.h |
| @comment POSIX.1 |
| @deftypefun int setpgid (pid_t @var{pid}, pid_t @var{pgid}) |
| The @code{setpgid} function puts the process @var{pid} into the process |
| group @var{pgid}. As a special case, either @var{pid} or @var{pgid} can |
| be zero to indicate the process ID of the calling process. |
| |
| This function fails on a system that does not support job control. |
| @xref{Job Control is Optional}, for more information. |
| |
| If the operation is successful, @code{setpgid} returns zero. Otherwise |
| it returns @code{-1}. The following @code{errno} error conditions are |
| defined for this function: |
| |
| @table @code |
| @item EACCES |
| The child process named by @var{pid} has executed an @code{exec} |
| function since it was forked. |
| |
| @item EINVAL |
| The value of the @var{pgid} is not valid. |
| |
| @item ENOSYS |
| The system doesn't support job control. |
| |
| @item EPERM |
| The process indicated by the @var{pid} argument is a session leader, |
| or is not in the same session as the calling process, or the value of |
| the @var{pgid} argument doesn't match a process group ID in the same |
| session as the calling process. |
| |
| @item ESRCH |
| The process indicated by the @var{pid} argument is not the calling |
| process or a child of the calling process. |
| @end table |
| @end deftypefun |
| |
| @comment unistd.h |
| @comment BSD |
| @deftypefun int setpgrp (pid_t @var{pid}, pid_t @var{pgid}) |
| This is the BSD Unix name for @code{setpgid}. Both functions do exactly |
| the same thing. |
| @end deftypefun |
| |
| |
| @node Terminal Access Functions, , Process Group Functions, Functions for Job Control |
| @subsection Functions for Controlling Terminal Access |
| |
| These are the functions for reading or setting the foreground |
| process group of a terminal. You should include the header files |
| @file{sys/types.h} and @file{unistd.h} in your application to use |
| these functions. |
| @pindex unistd.h |
| @pindex sys/types.h |
| |
| Although these functions take a file descriptor argument to specify |
| the terminal device, the foreground job is associated with the terminal |
| file itself and not a particular open file descriptor. |
| |
| @comment unistd.h |
| @comment POSIX.1 |
| @deftypefun pid_t tcgetpgrp (int @var{filedes}) |
| This function returns the process group ID of the foreground process |
| group associated with the terminal open on descriptor @var{filedes}. |
| |
| If there is no foreground process group, the return value is a number |
| greater than @code{1} that does not match the process group ID of any |
| existing process group. This can happen if all of the processes in the |
| job that was formerly the foreground job have terminated, and no other |
| job has yet been moved into the foreground. |
| |
| In case of an error, a value of @code{-1} is returned. The |
| following @code{errno} error conditions are defined for this function: |
| |
| @table @code |
| @item EBADF |
| The @var{filedes} argument is not a valid file descriptor. |
| |
| @item ENOSYS |
| The system doesn't support job control. |
| |
| @item ENOTTY |
| The terminal file associated with the @var{filedes} argument isn't the |
| controlling terminal of the calling process. |
| @end table |
| @end deftypefun |
| |
| @comment unistd.h |
| @comment POSIX.1 |
| @deftypefun int tcsetpgrp (int @var{filedes}, pid_t @var{pgid}) |
| This function is used to set a terminal's foreground process group ID. |
| The argument @var{filedes} is a descriptor which specifies the terminal; |
| @var{pgid} specifies the process group. The calling process must be a |
| member of the same session as @var{pgid} and must have the same |
| controlling terminal. |
| |
| For terminal access purposes, this function is treated as output. If it |
| is called from a background process on its controlling terminal, |
| normally all processes in the process group are sent a @code{SIGTTOU} |
| signal. The exception is if the calling process itself is ignoring or |
| blocking @code{SIGTTOU} signals, in which case the operation is |
| performed and no signal is sent. |
| |
| If successful, @code{tcsetpgrp} returns @code{0}. A return value of |
| @code{-1} indicates an error. The following @code{errno} error |
| conditions are defined for this function: |
| |
| @table @code |
| @item EBADF |
| The @var{filedes} argument is not a valid file descriptor. |
| |
| @item EINVAL |
| The @var{pgid} argument is not valid. |
| |
| @item ENOSYS |
| The system doesn't support job control. |
| |
| @item ENOTTY |
| The @var{filedes} isn't the controlling terminal of the calling process. |
| |
| @item EPERM |
| The @var{pgid} isn't a process group in the same session as the calling |
| process. |
| @end table |
| @end deftypefun |
| |
| @comment termios.h |
| @comment Unix98 |
| @deftypefun pid_t tcgetsid (int @var{fildes}) |
| This function is used to obtain the process group ID of the session |
| for which the terminal specified by @var{fildes} is the controlling terminal. |
| If the call is successful the group ID is returned. Otherwise the |
| return value is @code{(pid_t) -1} and the global variable @var{errno} |
| is set to the following value: |
| @table @code |
| @item EBADF |
| The @var{filedes} argument is not a valid file descriptor. |
| |
| @item ENOTTY |
| The calling process does not have a controlling terminal, or the file |
| is not the controlling terminal. |
| @end table |
| @end deftypefun |