6aa1f5995a
Add Caldera license. Approved by: David Taylor <davidt@caldera.com> Make buildable under FreeBSD.
578 lines
14 KiB
Plaintext
578 lines
14 KiB
Plaintext
.\" Copyright (C) Caldera International Inc. 2001-2002. All rights reserved.
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.\"
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.\" Redistribution and use in source and binary forms, with or without
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.\" modification, are permitted provided that the following conditions are
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.\" met:
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.\"
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.\" Redistributions of source code and documentation must retain the above
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.\" copyright notice, this list of conditions and the following
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.\" disclaimer.
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.\"
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.\" Redistributions in binary form must reproduce the above copyright
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.\" notice, this list of conditions and the following disclaimer in the
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.\" documentation and/or other materials provided with the distribution.
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.\"
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.\" All advertising materials mentioning features or use of this software
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.\" must display the following acknowledgement:
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.\"
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.\" This product includes software developed or owned by Caldera
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.\" International, Inc. Neither the name of Caldera International, Inc.
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.\" nor the names of other contributors may be used to endorse or promote
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.\" products derived from this software without specific prior written
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.\" permission.
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.\"
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.\" USE OF THE SOFTWARE PROVIDED FOR UNDER THIS LICENSE BY CALDERA
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.\" INTERNATIONAL, INC. AND CONTRIBUTORS ``AS IS'' AND ANY EXPRESS OR
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.\" IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
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.\" WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
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.\" DISCLAIMED. IN NO EVENT SHALL CALDERA INTERNATIONAL, INC. BE LIABLE
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.\" FOR ANY DIRECT, INDIRECT INCIDENTAL, SPECIAL, EXEMPLARY, OR
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.\" CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
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.\" SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
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.\" BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
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.\" WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
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.\" OR OTHERWISE) RISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
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.\" IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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.\"
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.\" $FreeBSD$
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.\"
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.\" @(#)p5 8.1 (Berkeley) 6/8/93
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.\"
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.NH
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PROCESSES
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.PP
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It is often easier to use a program written
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by someone else than to invent one's own.
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This section describes how to
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execute a program from within another.
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.NH 2
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The ``System'' Function
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.PP
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The easiest way to execute a program from another
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is to use
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the standard library routine
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.UL system .
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.UL system
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takes one argument, a command string exactly as typed
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at the terminal
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(except for the newline at the end)
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and executes it.
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For instance, to time-stamp the output of a program,
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.P1
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main()
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{
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system("date");
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/* rest of processing */
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}
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.P2
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If the command string has to be built from pieces,
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the in-memory formatting capabilities of
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.UL sprintf
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may be useful.
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.PP
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Remember than
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.UL getc
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and
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.UL putc
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normally buffer their input;
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terminal I/O will not be properly synchronized unless
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this buffering is defeated.
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For output, use
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.UL fflush ;
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for input, see
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.UL setbuf
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in the appendix.
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.NH 2
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Low-Level Process Creation \(em Execl and Execv
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.PP
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If you're not using the standard library,
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or if you need finer control over what
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happens,
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you will have to construct calls to other programs
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using the more primitive routines that the standard
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library's
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.UL system
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routine is based on.
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.PP
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The most basic operation is to execute another program
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.ul
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without
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.IT returning ,
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by using the routine
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.UL execl .
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To print the date as the last action of a running program,
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use
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.P1
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execl("/bin/date", "date", NULL);
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.P2
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The first argument to
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.UL execl
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is the
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.ul
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file name
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of the command; you have to know where it is found
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in the file system.
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The second argument is conventionally
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the program name
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(that is, the last component of the file name),
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but this is seldom used except as a place-holder.
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If the command takes arguments, they are strung out after
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this;
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the end of the list is marked by a
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.UL NULL
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argument.
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.PP
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The
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.UL execl
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call
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overlays the existing program with
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the new one,
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runs that, then exits.
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There is
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.ul
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no
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return to the original program.
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.PP
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More realistically,
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a program might fall into two or more phases
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that communicate only through temporary files.
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Here it is natural to make the second pass
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simply an
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.UL execl
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call from the first.
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.PP
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The one exception to the rule that the original program never gets control
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back occurs when there is an error, for example if the file can't be found
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or is not executable.
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If you don't know where
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.UL date
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is located, say
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.P1
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execl("/bin/date", "date", NULL);
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execl("/usr/bin/date", "date", NULL);
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fprintf(stderr, "Someone stole 'date'\en");
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.P2
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.PP
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A variant of
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.UL execl
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called
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.UL execv
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is useful when you don't know in advance how many arguments there are going to be.
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The call is
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.P1
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execv(filename, argp);
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.P2
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where
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.UL argp
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is an array of pointers to the arguments;
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the last pointer in the array must be
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.UL NULL
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so
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.UL execv
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can tell where the list ends.
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As with
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.UL execl ,
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.UL filename
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is the file in which the program is found, and
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.UL argp[0]
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is the name of the program.
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(This arrangement is identical to the
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.UL argv
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array for program arguments.)
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.PP
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Neither of these routines provides the niceties of normal command execution.
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There is no automatic search of multiple directories \(em
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you have to know precisely where the command is located.
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Nor do you get the expansion of metacharacters like
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.UL < ,
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.UL > ,
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.UL * ,
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.UL ? ,
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and
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.UL []
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in the argument list.
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If you want these, use
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.UL execl
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to invoke the shell
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.UL sh ,
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which then does all the work.
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Construct a string
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.UL commandline
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that contains the complete command as it would have been typed
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at the terminal, then say
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.P1
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execl("/bin/sh", "sh", "-c", commandline, NULL);
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.P2
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The shell is assumed to be at a fixed place,
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.UL /bin/sh .
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Its argument
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.UL -c
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says to treat the next argument
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as a whole command line, so it does just what you want.
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The only problem is in constructing the right information
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in
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.UL commandline .
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.NH 2
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Control of Processes \(em Fork and Wait
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.PP
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So far what we've talked about isn't really all that useful by itself.
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Now we will show how to regain control after running
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a program with
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.UL execl
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or
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.UL execv .
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Since these routines simply overlay the new program on the old one,
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to save the old one requires that it first be split into
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two copies;
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one of these can be overlaid, while the other waits for the new,
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overlaying program to finish.
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The splitting is done by a routine called
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.UL fork :
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.P1
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proc_id = fork();
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.P2
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splits the program into two copies, both of which continue to run.
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The only difference between the two is the value of
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.UL proc_id ,
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the ``process id.''
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In one of these processes (the ``child''),
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.UL proc_id
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is zero.
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In the other
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(the ``parent''),
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.UL proc_id
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is non-zero; it is the process number of the child.
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Thus the basic way to call, and return from,
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another program is
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.P1
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if (fork() == 0)
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execl("/bin/sh", "sh", "-c", cmd, NULL); /* in child */
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.P2
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And in fact, except for handling errors, this is sufficient.
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The
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.UL fork
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makes two copies of the program.
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In the child, the value returned by
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.UL fork
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is zero, so it calls
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.UL execl
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which does the
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.UL command
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and then dies.
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In the parent,
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.UL fork
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returns non-zero
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so it skips the
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.UL execl.
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(If there is any error,
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.UL fork
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returns
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.UL -1 ).
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.PP
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More often, the parent wants to wait for the child to terminate
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before continuing itself.
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This can be done with
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the function
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.UL wait :
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.P1
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int status;
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if (fork() == 0)
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execl(...);
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wait(&status);
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.P2
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This still doesn't handle any abnormal conditions, such as a failure
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of the
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.UL execl
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or
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.UL fork ,
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or the possibility that there might be more than one child running simultaneously.
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(The
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.UL wait
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returns the
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process id
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of the terminated child, if you want to check it against the value
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returned by
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.UL fork .)
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Finally, this fragment doesn't deal with any
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funny behavior on the part of the child
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(which is reported in
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.UL status ).
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Still, these three lines
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are the heart of the standard library's
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.UL system
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routine,
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which we'll show in a moment.
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.PP
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The
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.UL status
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returned by
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.UL wait
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encodes in its low-order eight bits
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the system's idea of the child's termination status;
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it is 0 for normal termination and non-zero to indicate
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various kinds of problems.
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The next higher eight bits are taken from the argument
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of the call to
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.UL exit
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which caused a normal termination of the child process.
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It is good coding practice
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for all programs to return meaningful
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status.
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.PP
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When a program is called by the shell,
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the three file descriptors
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0, 1, and 2 are set up pointing at the right files,
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and all other possible file descriptors
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are available for use.
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When this program calls another one,
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correct etiquette suggests making sure the same conditions
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hold.
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Neither
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.UL fork
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nor the
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.UL exec
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calls affects open files in any way.
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If the parent is buffering output
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that must come out before output from the child,
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the parent must flush its buffers
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before the
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.UL execl .
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Conversely,
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if a caller buffers an input stream,
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the called program will lose any information
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that has been read by the caller.
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.NH 2
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Pipes
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.PP
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A
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.ul
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pipe
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is an I/O channel intended for use
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between two cooperating processes:
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one process writes into the pipe,
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while the other reads.
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The system looks after buffering the data and synchronizing
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the two processes.
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Most pipes are created by the shell,
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as in
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.P1
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ls | pr
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.P2
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which connects the standard output of
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.UL ls
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to the standard input of
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.UL pr .
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Sometimes, however, it is most convenient
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for a process to set up its own plumbing;
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in this section, we will illustrate how
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the pipe connection is established and used.
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.PP
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The system call
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.UL pipe
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creates a pipe.
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Since a pipe is used for both reading and writing,
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two file descriptors are returned;
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the actual usage is like this:
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.P1
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int fd[2];
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stat = pipe(fd);
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if (stat == -1)
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/* there was an error ... */
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.P2
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.UL fd
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is an array of two file descriptors, where
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.UL fd[0]
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is the read side of the pipe and
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.UL fd[1]
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is for writing.
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These may be used in
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.UL read ,
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.UL write
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and
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.UL close
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calls just like any other file descriptors.
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.PP
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If a process reads a pipe which is empty,
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it will wait until data arrives;
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if a process writes into a pipe which
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is too full, it will wait until the pipe empties somewhat.
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If the write side of the pipe is closed,
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a subsequent
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.UL read
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will encounter end of file.
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.PP
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To illustrate the use of pipes in a realistic setting,
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let us write a function called
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.UL popen(cmd,\ mode) ,
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which creates a process
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.UL cmd
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(just as
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.UL system
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does),
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and returns a file descriptor that will either
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read or write that process, according to
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.UL mode .
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That is,
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the call
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.P1
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fout = popen("pr", WRITE);
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.P2
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creates a process that executes
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the
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.UL pr
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command;
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subsequent
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.UL write
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calls using the file descriptor
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.UL fout
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will send their data to that process
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through the pipe.
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.PP
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.UL popen
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first creates the
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the pipe with a
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.UL pipe
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system call;
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it then
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.UL fork s
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to create two copies of itself.
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The child decides whether it is supposed to read or write,
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closes the other side of the pipe,
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then calls the shell (via
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.UL execl )
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to run the desired process.
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The parent likewise closes the end of the pipe it does not use.
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These closes are necessary to make end-of-file tests work properly.
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For example, if a child that intends to read
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fails to close the write end of the pipe, it will never
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see the end of the pipe file, just because there is one writer
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potentially active.
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.P1
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#include <stdio.h>
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#define READ 0
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#define WRITE 1
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#define tst(a, b) (mode == READ ? (b) : (a))
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static int popen_pid;
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popen(cmd, mode)
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char *cmd;
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int mode;
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{
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int p[2];
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if (pipe(p) < 0)
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return(NULL);
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if ((popen_pid = fork()) == 0) {
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close(tst(p[WRITE], p[READ]));
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close(tst(0, 1));
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dup(tst(p[READ], p[WRITE]));
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close(tst(p[READ], p[WRITE]));
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execl("/bin/sh", "sh", "-c", cmd, 0);
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_exit(1); /* disaster has occurred if we get here */
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}
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if (popen_pid == -1)
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return(NULL);
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close(tst(p[READ], p[WRITE]));
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return(tst(p[WRITE], p[READ]));
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}
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.P2
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The sequence of
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.UL close s
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in the child
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is a bit tricky.
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Suppose
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that the task is to create a child process that will read data from the parent.
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Then the first
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.UL close
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closes the write side of the pipe,
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leaving the read side open.
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The lines
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.P1
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close(tst(0, 1));
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dup(tst(p[READ], p[WRITE]));
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.P2
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are the conventional way to associate the pipe descriptor
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with the standard input of the child.
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The
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.UL close
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closes file descriptor 0,
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that is, the standard input.
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.UL dup
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is a system call that
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returns a duplicate of an already open file descriptor.
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File descriptors are assigned in increasing order
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and the first available one is returned,
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so
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the effect of the
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.UL dup
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is to copy the file descriptor for the pipe (read side)
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to file descriptor 0;
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thus the read side of the pipe becomes the standard input.
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(Yes, this is a bit tricky, but it's a standard idiom.)
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Finally, the old read side of the pipe is closed.
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.PP
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A similar sequence of operations takes place
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when the child process is supposed to write
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from the parent instead of reading.
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You may find it a useful exercise to step through that case.
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.PP
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The job is not quite done,
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for we still need a function
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.UL pclose
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to close the pipe created by
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.UL popen .
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The main reason for using a separate function rather than
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.UL close
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is that it is desirable to wait for the termination of the child process.
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First, the return value from
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.UL pclose
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indicates whether the process succeeded.
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Equally important when a process creates several children
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is that only a bounded number of unwaited-for children
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can exist, even if some of them have terminated;
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performing the
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.UL wait
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lays the child to rest.
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Thus:
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.P1
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#include <signal.h>
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pclose(fd) /* close pipe fd */
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int fd;
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{
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register r, (*hstat)(), (*istat)(), (*qstat)();
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int status;
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extern int popen_pid;
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close(fd);
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istat = signal(SIGINT, SIG_IGN);
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qstat = signal(SIGQUIT, SIG_IGN);
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hstat = signal(SIGHUP, SIG_IGN);
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while ((r = wait(&status)) != popen_pid && r != -1);
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if (r == -1)
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status = -1;
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signal(SIGINT, istat);
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signal(SIGQUIT, qstat);
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signal(SIGHUP, hstat);
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return(status);
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}
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.P2
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The calls to
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.UL signal
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make sure that no interrupts, etc.,
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interfere with the waiting process;
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this is the topic of the next section.
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.PP
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The routine as written has the limitation that only one pipe may
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be open at once, because of the single shared variable
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.UL popen_pid ;
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it really should be an array indexed by file descriptor.
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A
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.UL popen
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function, with slightly different arguments and return value is available
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as part of the standard I/O library discussed below.
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As currently written, it shares the same limitation.
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