9e4ded5d0e
(I think I'm up to part 6.)
1300 lines
31 KiB
Plaintext
1300 lines
31 KiB
Plaintext
.\"
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.\" Must use -- tbl -- for this one
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.\"
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.\" @(#)rpcgen.ms 2.2 88/08/04 4.0 RPCSRC
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.de BT
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.if \\n%=1 .tl ''- % -''
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..
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.ND
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.\" prevent excess underlining in nroff
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.if n .fp 2 R
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.OH '\fBrpcgen\fP Programming Guide''Page %'
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.EH 'Page %''\fBrpcgen\fP Programming Guide'
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.if \\n%=1 .bp
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.SH
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\&\fBrpcgen\fP Programming Guide
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.NH 0
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\&The \fBrpcgen\fP Protocol Compiler
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.IX rpcgen "" \fIrpcgen\fP "" PAGE MAJOR
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.LP
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.IX RPC "" "" \fIrpcgen\fP
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The details of programming applications to use Remote Procedure Calls
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can be overwhelming. Perhaps most daunting is the writing of the XDR
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routines necessary to convert procedure arguments and results into
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their network format and vice-versa.
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.LP
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Fortunately,
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.I rpcgen(1)
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exists to help programmers write RPC applications simply and directly.
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.I rpcgen
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does most of the dirty work, allowing programmers to debug
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the main features of their application, instead of requiring them to
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spend most of their time debugging their network interface code.
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.LP
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.I rpcgen
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is a compiler. It accepts a remote program interface definition written
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in a language, called RPC Language, which is similar to C. It produces a C
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language output which includes stub versions of the client routines, a
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server skeleton, XDR filter routines for both parameters and results, and a
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header file that contains common definitions. The client stubs interface
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with the RPC library and effectively hide the network from their callers.
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The server stub similarly hides the network from the server procedures that
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are to be invoked by remote clients.
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.I rpcgen 's
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output files can be compiled and linked in the usual way. The developer
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writes server procedures\(emin any language that observes Sun calling
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conventions\(emand links them with the server skeleton produced by
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.I rpcgen
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to get an executable server program. To use a remote program, a programmer
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writes an ordinary main program that makes local procedure calls to the
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client stubs produced by
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.I rpcgen .
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Linking this program with
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.I rpcgen 's
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stubs creates an executable program. (At present the main program must be
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written in C).
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.I rpcgen
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options can be used to suppress stub generation and to specify the transport
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to be used by the server stub.
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.LP
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Like all compilers,
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.I rpcgen
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reduces development time
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that would otherwise be spent coding and debugging low-level routines.
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All compilers, including
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.I rpcgen ,
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do this at a small cost in efficiency
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and flexibility. However, many compilers allow escape hatches for
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programmers to mix low-level code with high-level code.
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.I rpcgen
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is no exception. In speed-critical applications, hand-written routines
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can be linked with the
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.I rpcgen
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output without any difficulty. Also, one may proceed by using
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.I rpcgen
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output as a starting point, and then rewriting it as necessary.
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(If you need a discussion of RPC programming without
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.I rpcgen ,
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see the
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.I "Remote Procedure Call Programming Guide)\.
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.NH 1
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\&Converting Local Procedures into Remote Procedures
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.IX rpcgen "local procedures" \fIrpcgen\fP
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.IX rpcgen "remote procedures" \fIrpcgen\fP
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.LP
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Assume an application that runs on a single machine, one which we want
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to convert to run over the network. Here we will demonstrate such a
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conversion by way of a simple example\(ema program that prints a
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message to the console:
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.ie t .DS
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.el .DS L
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.ft I
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/*
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* printmsg.c: print a message on the console
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*/
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.ft CW
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#include <stdio.h>
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main(argc, argv)
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int argc;
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char *argv[];
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{
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char *message;
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if (argc < 2) {
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fprintf(stderr, "usage: %s <message>\en", argv[0]);
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exit(1);
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}
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message = argv[1];
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if (!printmessage(message)) {
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fprintf(stderr, "%s: couldn't print your message\en",
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argv[0]);
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exit(1);
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}
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printf("Message Delivered!\en");
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exit(0);
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}
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.ft I
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/*
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* Print a message to the console.
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* Return a boolean indicating whether the message was actually printed.
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*/
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.ft CW
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printmessage(msg)
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char *msg;
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{
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FILE *f;
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f = fopen("/dev/console", "w");
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if (f == NULL) {
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return (0);
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}
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fprintf(f, "%s\en", msg);
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fclose(f);
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return(1);
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}
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.DE
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.LP
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And then, of course:
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.ie t .DS
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.el .DS L
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.ft CW
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example% \fBcc printmsg.c -o printmsg\fP
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example% \fBprintmsg "Hello, there."\fP
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Message delivered!
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example%
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.DE
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.LP
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If
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.I printmessage()
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was turned into a remote procedure,
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then it could be called from anywhere in the network.
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Ideally, one would just like to stick a keyword like
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.I remote
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in front of a
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procedure to turn it into a remote procedure. Unfortunately,
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we have to live within the constraints of the C language, since
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it existed long before RPC did. But even without language
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support, it's not very difficult to make a procedure remote.
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.LP
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In general, it's necessary to figure out what the types are for
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all procedure inputs and outputs. In this case, we have a
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procedure
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.I printmessage()
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which takes a string as input, and returns an integer
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as output. Knowing this, we can write a protocol specification in RPC
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language that describes the remote version of
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.I printmessage ().
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Here it is:
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.ie t .DS
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.el .DS L
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.ft I
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/*
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* msg.x: Remote message printing protocol
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*/
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.ft CW
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program MESSAGEPROG {
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version MESSAGEVERS {
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int PRINTMESSAGE(string) = 1;
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} = 1;
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} = 99;
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.DE
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.LP
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Remote procedures are part of remote programs, so we actually declared
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an entire remote program here which contains the single procedure
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.I PRINTMESSAGE .
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This procedure was declared to be in version 1 of the
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remote program. No null procedure (procedure 0) is necessary because
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.I rpcgen
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generates it automatically.
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.LP
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Notice that everything is declared with all capital letters. This is
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not required, but is a good convention to follow.
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.LP
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Notice also that the argument type is \*Qstring\*U and not \*Qchar *\*U. This
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is because a \*Qchar *\*U in C is ambiguous. Programmers usually intend it
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to mean a null-terminated string of characters, but it could also
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represent a pointer to a single character or a pointer to an array of
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characters. In RPC language, a null-terminated string is
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unambiguously called a \*Qstring\*U.
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.LP
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There are just two more things to write. First, there is the remote
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procedure itself. Here's the definition of a remote procedure
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to implement the
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.I PRINTMESSAGE
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procedure we declared above:
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.ie t .DS
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.el .DS L
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.vs 11
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.ft I
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/*
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* msg_proc.c: implementation of the remote procedure "printmessage"
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*/
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.ft CW
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#include <stdio.h>
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#include <rpc/rpc.h> /* \fIalways needed\fP */
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#include "msg.h" /* \fIneed this too: msg.h will be generated by rpcgen\fP */
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.ft I
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/*
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* Remote verson of "printmessage"
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*/
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.ft CW
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int *
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printmessage_1(msg)
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char **msg;
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{
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static int result; /* \fImust be static!\fP */
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FILE *f;
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f = fopen("/dev/console", "w");
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if (f == NULL) {
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result = 0;
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return (&result);
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}
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fprintf(f, "%s\en", *msg);
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fclose(f);
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result = 1;
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return (&result);
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}
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.vs
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.DE
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.LP
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Notice here that the declaration of the remote procedure
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.I printmessage_1()
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differs from that of the local procedure
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.I printmessage()
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in three ways:
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.IP 1.
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It takes a pointer to a string instead of a string itself. This
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is true of all remote procedures: they always take pointers to their
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arguments rather than the arguments themselves.
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.IP 2.
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It returns a pointer to an integer instead of an integer itself. This is
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also generally true of remote procedures: they always return a pointer
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to their results.
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.IP 3.
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It has an \*Q_1\*U appended to its name. In general, all remote
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procedures called by
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.I rpcgen
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are named by the following rule: the name in the program definition
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(here
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.I PRINTMESSAGE )
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is converted to all
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lower-case letters, an underbar (\*Q_\*U) is appended to it, and
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finally the version number (here 1) is appended.
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.LP
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The last thing to do is declare the main client program that will call
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the remote procedure. Here it is:
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.ie t .DS
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.el .DS L
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.ft I
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/*
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* rprintmsg.c: remote version of "printmsg.c"
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*/
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.ft CW
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#include <stdio.h>
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#include <rpc/rpc.h> /* \fIalways needed\fP */
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#include "msg.h" /* \fIneed this too: msg.h will be generated by rpcgen\fP */
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main(argc, argv)
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int argc;
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char *argv[];
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{
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CLIENT *cl;
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int *result;
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char *server;
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char *message;
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if (argc < 3) {
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fprintf(stderr, "usage: %s host message\en", argv[0]);
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exit(1);
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}
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.ft I
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/*
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* Save values of command line arguments
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*/
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.ft CW
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server = argv[1];
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message = argv[2];
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.ft I
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/*
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* Create client "handle" used for calling \fIMESSAGEPROG\fP on the
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* server designated on the command line. We tell the RPC package
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* to use the "tcp" protocol when contacting the server.
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*/
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.ft CW
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cl = clnt_create(server, MESSAGEPROG, MESSAGEVERS, "tcp");
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if (cl == NULL) {
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.ft I
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/*
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* Couldn't establish connection with server.
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* Print error message and die.
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*/
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.ft CW
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clnt_pcreateerror(server);
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exit(1);
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}
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.ft I
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/*
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* Call the remote procedure "printmessage" on the server
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*/
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.ft CW
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result = printmessage_1(&message, cl);
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if (result == NULL) {
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.ft I
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/*
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* An error occurred while calling the server.
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* Print error message and die.
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*/
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.ft CW
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clnt_perror(cl, server);
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exit(1);
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}
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.ft I
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/*
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* Okay, we successfully called the remote procedure.
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*/
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.ft CW
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if (*result == 0) {
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.ft I
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/*
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* Server was unable to print our message.
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* Print error message and die.
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*/
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.ft CW
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fprintf(stderr, "%s: %s couldn't print your message\en",
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argv[0], server);
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exit(1);
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}
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.ft I
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/*
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* The message got printed on the server's console
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*/
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.ft CW
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printf("Message delivered to %s!\en", server);
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}
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.DE
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There are two things to note here:
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.IP 1.
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.IX "client handle, used by rpcgen" "" "client handle, used by \fIrpcgen\fP"
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First a client \*Qhandle\*U is created using the RPC library routine
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.I clnt_create ().
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This client handle will be passed to the stub routines
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which call the remote procedure.
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.IP 2.
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The remote procedure
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.I printmessage_1()
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is called exactly the same way as it is declared in
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.I msg_proc.c
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except for the inserted client handle as the first argument.
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.LP
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Here's how to put all of the pieces together:
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.ie t .DS
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.el .DS L
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.ft CW
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example% \fBrpcgen msg.x\fP
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example% \fBcc rprintmsg.c msg_clnt.c -o rprintmsg\fP
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example% \fBcc msg_proc.c msg_svc.c -o msg_server\fP
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.DE
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Two programs were compiled here: the client program
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.I rprintmsg
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and the server program
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.I msg_server .
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Before doing this though,
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.I rpcgen
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was used to fill in the missing pieces.
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.LP
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Here is what
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.I rpcgen
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did with the input file
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.I msg.x :
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.IP 1.
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It created a header file called
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.I msg.h
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that contained
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.I #define 's
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for
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.I MESSAGEPROG ,
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.I MESSAGEVERS
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and
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.I PRINTMESSAGE
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for use in the other modules.
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.IP 2.
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It created client \*Qstub\*U routines in the
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.I msg_clnt.c
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file. In this case there is only one, the
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.I printmessage_1()
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that was referred to from the
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.I printmsg
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client program. The name of the output file for
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client stub routines is always formed in this way: if the name of the
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input file is
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.I FOO.x ,
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the client stubs output file is called
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.I FOO_clnt.c .
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.IP 3.
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It created the server program which calls
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.I printmessage_1()
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in
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.I msg_proc.c .
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This server program is named
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.I msg_svc.c .
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The rule for naming the server output file is similar to the
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previous one: for an input file called
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.I FOO.x ,
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the output server file is named
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.I FOO_svc.c .
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.LP
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Now we're ready to have some fun. First, copy the server to a
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remote machine and run it. For this example, the
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machine is called \*Qmoon\*U. Server processes are run in the
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background, because they never exit.
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.ie t .DS
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.el .DS L
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.ft CW
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moon% \fBmsg_server &\fP
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.DE
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|
Then on our local machine (\*Qsun\*U) we can print a message on \*Qmoon\*Us
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console.
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.ie t .DS
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.el .DS L
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.ft CW
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sun% \fBprintmsg moon "Hello, moon."\fP
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.DE
|
|
The message will get printed to \*Qmoon\*Us console. You can print a
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message on anybody's console (including your own) with this program if
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you are able to copy the server to their machine and run it.
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.NH 1
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\&Generating XDR Routines
|
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.IX RPC "generating XDR routines"
|
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.LP
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The previous example only demonstrated the automatic generation of
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client and server RPC code.
|
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.I rpcgen
|
|
may also be used to generate XDR routines, that is, the routines
|
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necessary to convert local data
|
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structures into network format and vice-versa. This example presents
|
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a complete RPC service\(ema remote directory listing service, which uses
|
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.I rpcgen
|
|
not only to generate stub routines, but also to generate the XDR
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routines. Here is the protocol description file:
|
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.ie t .DS
|
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.el .DS L
|
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.ft I
|
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/*
|
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* dir.x: Remote directory listing protocol
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*/
|
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.ft CW
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const MAXNAMELEN = 255; /* \fImaximum length of a directory entry\fP */
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typedef string nametype<MAXNAMELEN>; /* \fIa directory entry\fP */
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typedef struct namenode *namelist; /* \fIa link in the listing\fP */
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.ft I
|
|
/*
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* A node in the directory listing
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*/
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.ft CW
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struct namenode {
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nametype name; /* \fIname of directory entry\fP */
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namelist next; /* \fInext entry\fP */
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};
|
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|
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.ft I
|
|
/*
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* The result of a READDIR operation.
|
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*/
|
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.ft CW
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union readdir_res switch (int errno) {
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case 0:
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namelist list; /* \fIno error: return directory listing\fP */
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default:
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void; /* \fIerror occurred: nothing else to return\fP */
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};
|
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|
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.ft I
|
|
/*
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* The directory program definition
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*/
|
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.ft CW
|
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program DIRPROG {
|
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version DIRVERS {
|
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readdir_res
|
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READDIR(nametype) = 1;
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} = 1;
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} = 76;
|
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.DE
|
|
.SH
|
|
Note:
|
|
.I
|
|
Types (like
|
|
.I readdir_res
|
|
in the example above) can be defined using
|
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the \*Qstruct\*U, \*Qunion\*U and \*Qenum\*U keywords, but those keywords
|
|
should not be used in subsequent declarations of variables of those types.
|
|
For example, if you define a union \*Qfoo\*U, you should declare using
|
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only \*Qfoo\*U and not \*Qunion foo\*U. In fact,
|
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.I rpcgen
|
|
compiles
|
|
RPC unions into C structures and it is an error to declare them using the
|
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\*Qunion\*U keyword.
|
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.LP
|
|
Running
|
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.I rpcgen
|
|
on
|
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.I dir.x
|
|
creates four output files. Three are the same as before: header file,
|
|
client stub routines and server skeleton. The fourth are the XDR routines
|
|
necessary for converting the data types we declared into XDR format and
|
|
vice-versa. These are output in the file
|
|
.I dir_xdr.c .
|
|
.LP
|
|
Here is the implementation of the
|
|
.I READDIR
|
|
procedure.
|
|
.ie t .DS
|
|
.el .DS L
|
|
.vs 11
|
|
.ft I
|
|
/*
|
|
* dir_proc.c: remote readdir implementation
|
|
*/
|
|
.ft CW
|
|
#include <rpc/rpc.h>
|
|
#include <sys/dir.h>
|
|
#include "dir.h"
|
|
|
|
extern int errno;
|
|
extern char *malloc();
|
|
extern char *strdup();
|
|
|
|
readdir_res *
|
|
readdir_1(dirname)
|
|
nametype *dirname;
|
|
{
|
|
DIR *dirp;
|
|
struct direct *d;
|
|
namelist nl;
|
|
namelist *nlp;
|
|
static readdir_res res; /* \fImust be static\fP! */
|
|
|
|
.ft I
|
|
/*
|
|
* Open directory
|
|
*/
|
|
.ft CW
|
|
dirp = opendir(*dirname);
|
|
if (dirp == NULL) {
|
|
res.errno = errno;
|
|
return (&res);
|
|
}
|
|
|
|
.ft I
|
|
/*
|
|
* Free previous result
|
|
*/
|
|
.ft CW
|
|
xdr_free(xdr_readdir_res, &res);
|
|
|
|
.ft I
|
|
/*
|
|
* Collect directory entries.
|
|
* Memory allocated here will be freed by \fIxdr_free\fP
|
|
* next time \fIreaddir_1\fP is called
|
|
*/
|
|
.ft CW
|
|
nlp = &res.readdir_res_u.list;
|
|
while (d = readdir(dirp)) {
|
|
nl = *nlp = (namenode *) malloc(sizeof(namenode));
|
|
nl->name = strdup(d->d_name);
|
|
nlp = &nl->next;
|
|
}
|
|
*nlp = NULL;
|
|
|
|
.ft I
|
|
/*
|
|
* Return the result
|
|
*/
|
|
.ft CW
|
|
res.errno = 0;
|
|
closedir(dirp);
|
|
return (&res);
|
|
}
|
|
.vs
|
|
.DE
|
|
Finally, there is the client side program to call the server:
|
|
.ie t .DS
|
|
.el .DS L
|
|
.ft I
|
|
/*
|
|
* rls.c: Remote directory listing client
|
|
*/
|
|
.ft CW
|
|
#include <stdio.h>
|
|
#include <rpc/rpc.h> /* \fIalways need this\fP */
|
|
#include "dir.h" /* \fIwill be generated by rpcgen\fI */
|
|
|
|
extern int errno;
|
|
|
|
main(argc, argv)
|
|
int argc;
|
|
char *argv[];
|
|
{
|
|
CLIENT *cl;
|
|
char *server;
|
|
char *dir;
|
|
readdir_res *result;
|
|
namelist nl;
|
|
|
|
|
|
if (argc != 3) {
|
|
fprintf(stderr, "usage: %s host directory\en",
|
|
argv[0]);
|
|
exit(1);
|
|
}
|
|
|
|
.ft I
|
|
/*
|
|
* Remember what our command line arguments refer to
|
|
*/
|
|
.ft CW
|
|
server = argv[1];
|
|
dir = argv[2];
|
|
|
|
.ft I
|
|
/*
|
|
* Create client "handle" used for calling \fIMESSAGEPROG\fP on the
|
|
* server designated on the command line. We tell the RPC package
|
|
* to use the "tcp" protocol when contacting the server.
|
|
*/
|
|
.ft CW
|
|
cl = clnt_create(server, DIRPROG, DIRVERS, "tcp");
|
|
if (cl == NULL) {
|
|
.ft I
|
|
/*
|
|
* Couldn't establish connection with server.
|
|
* Print error message and die.
|
|
*/
|
|
.ft CW
|
|
clnt_pcreateerror(server);
|
|
exit(1);
|
|
}
|
|
|
|
.ft I
|
|
/*
|
|
* Call the remote procedure \fIreaddir\fP on the server
|
|
*/
|
|
.ft CW
|
|
result = readdir_1(&dir, cl);
|
|
if (result == NULL) {
|
|
.ft I
|
|
/*
|
|
* An error occurred while calling the server.
|
|
* Print error message and die.
|
|
*/
|
|
.ft CW
|
|
clnt_perror(cl, server);
|
|
exit(1);
|
|
}
|
|
|
|
.ft I
|
|
/*
|
|
* Okay, we successfully called the remote procedure.
|
|
*/
|
|
.ft CW
|
|
if (result->errno != 0) {
|
|
.ft I
|
|
/*
|
|
* A remote system error occurred.
|
|
* Print error message and die.
|
|
*/
|
|
.ft CW
|
|
errno = result->errno;
|
|
perror(dir);
|
|
exit(1);
|
|
}
|
|
|
|
.ft I
|
|
/*
|
|
* Successfully got a directory listing.
|
|
* Print it out.
|
|
*/
|
|
.ft CW
|
|
for (nl = result->readdir_res_u.list; nl != NULL;
|
|
nl = nl->next) {
|
|
printf("%s\en", nl->name);
|
|
}
|
|
exit(0);
|
|
}
|
|
.DE
|
|
Compile everything, and run.
|
|
.DS
|
|
.ft CW
|
|
sun% \fBrpcgen dir.x\fP
|
|
sun% \fBcc rls.c dir_clnt.c dir_xdr.c -o rls\fP
|
|
sun% \fBcc dir_svc.c dir_proc.c dir_xdr.c -o dir_svc\fP
|
|
|
|
sun% \fBdir_svc &\fP
|
|
|
|
moon% \fBrls sun /usr/pub\fP
|
|
\&.
|
|
\&..
|
|
ascii
|
|
eqnchar
|
|
greek
|
|
kbd
|
|
marg8
|
|
tabclr
|
|
tabs
|
|
tabs4
|
|
moon%
|
|
.DE
|
|
.LP
|
|
.IX "debugging with rpcgen" "" "debugging with \fIrpcgen\fP"
|
|
A final note about
|
|
.I rpcgen :
|
|
The client program and the server procedure can be tested together
|
|
as a single program by simply linking them with each other rather
|
|
than with the client and server stubs. The procedure calls will be
|
|
executed as ordinary local procedure calls and the program can be
|
|
debugged with a local debugger such as
|
|
.I dbx .
|
|
When the program is working, the client program can be linked to
|
|
the client stub produced by
|
|
.I rpcgen
|
|
and the server procedures can be linked to the server stub produced
|
|
by
|
|
.I rpcgen .
|
|
.SH
|
|
.I NOTE :
|
|
\fIIf you do this, you may want to comment out calls to RPC library
|
|
routines, and have client-side routines call server routines
|
|
directly.\fP
|
|
.LP
|
|
.NH 1
|
|
\&The C-Preprocessor
|
|
.IX rpcgen "C-preprocessor" \fIrpcgen\fP
|
|
.LP
|
|
The C-preprocessor is run on all input files before they are
|
|
compiled, so all the preprocessor directives are legal within a \*Q.x\*U
|
|
file. Four symbols may be defined, depending upon which output file is
|
|
getting generated. The symbols are:
|
|
.TS
|
|
box tab (&);
|
|
lfI lfI
|
|
lfL l .
|
|
Symbol&Usage
|
|
_
|
|
RPC_HDR&for header-file output
|
|
RPC_XDR&for XDR routine output
|
|
RPC_SVC&for server-skeleton output
|
|
RPC_CLNT&for client stub output
|
|
.TE
|
|
.LP
|
|
Also,
|
|
.I rpcgen
|
|
does a little preprocessing of its own. Any line that
|
|
begins with a percent sign is passed directly into the output file,
|
|
without any interpretation of the line. Here is a simple example that
|
|
demonstrates the preprocessing features.
|
|
.ie t .DS
|
|
.el .DS L
|
|
.ft I
|
|
/*
|
|
* time.x: Remote time protocol
|
|
*/
|
|
.ft CW
|
|
program TIMEPROG {
|
|
version TIMEVERS {
|
|
unsigned int TIMEGET(void) = 1;
|
|
} = 1;
|
|
} = 44;
|
|
|
|
#ifdef RPC_SVC
|
|
%int *
|
|
%timeget_1()
|
|
%{
|
|
% static int thetime;
|
|
%
|
|
% thetime = time(0);
|
|
% return (&thetime);
|
|
%}
|
|
#endif
|
|
.DE
|
|
The '%' feature is not generally recommended, as there is no guarantee
|
|
that the compiler will stick the output where you intended.
|
|
.NH 1
|
|
\&\fBrpcgen\fP Programming Notes
|
|
.IX rpcgen "other operations" \fIrpcgen\fP
|
|
.sp
|
|
.NH 2
|
|
\&Timeout Changes
|
|
.IX rpcgen "timeout changes" \fIrpcgen\fP
|
|
.LP
|
|
RPC sets a default timeout of 25 seconds for RPC calls when
|
|
.I clnt_create()
|
|
is used. This timeout may be changed using
|
|
.I clnt_control()
|
|
Here is a small code fragment to demonstrate use of
|
|
.I clnt_control ():
|
|
.ID
|
|
struct timeval tv;
|
|
CLIENT *cl;
|
|
.sp .5
|
|
cl = clnt_create("somehost", SOMEPROG, SOMEVERS, "tcp");
|
|
if (cl == NULL) {
|
|
exit(1);
|
|
}
|
|
tv.tv_sec = 60; /* \fIchange timeout to 1 minute\fP */
|
|
tv.tv_usec = 0;
|
|
clnt_control(cl, CLSET_TIMEOUT, &tv);
|
|
.DE
|
|
.NH 2
|
|
\&Handling Broadcast on the Server Side
|
|
.IX "broadcast RPC"
|
|
.IX rpcgen "broadcast RPC" \fIrpcgen\fP
|
|
.LP
|
|
When a procedure is known to be called via broadcast RPC,
|
|
it is usually wise for the server to not reply unless it can provide
|
|
some useful information to the client. This prevents the network
|
|
from getting flooded by useless replies.
|
|
.LP
|
|
To prevent the server from replying, a remote procedure can
|
|
return NULL as its result, and the server code generated by
|
|
.I rpcgen
|
|
will detect this and not send out a reply.
|
|
.LP
|
|
Here is an example of a procedure that replies only if it
|
|
thinks it is an NFS server:
|
|
.ID
|
|
void *
|
|
reply_if_nfsserver()
|
|
{
|
|
char notnull; /* \fIjust here so we can use its address\fP */
|
|
.sp .5
|
|
if (access("/etc/exports", F_OK) < 0) {
|
|
return (NULL); /* \fIprevent RPC from replying\fP */
|
|
}
|
|
.ft I
|
|
/*
|
|
* return non-null pointer so RPC will send out a reply
|
|
*/
|
|
.ft L
|
|
return ((void *)¬null);
|
|
}
|
|
.DE
|
|
Note that if procedure returns type \*Qvoid *\*U, they must return a non-NULL
|
|
pointer if they want RPC to reply for them.
|
|
.NH 2
|
|
\&Other Information Passed to Server Procedures
|
|
.LP
|
|
Server procedures will often want to know more about an RPC call
|
|
than just its arguments. For example, getting authentication information
|
|
is important to procedures that want to implement some level of security.
|
|
This extra information is actually supplied to the server procedure as a
|
|
second argument. Here is an example to demonstrate its use. What we've
|
|
done here is rewrite the previous
|
|
.I printmessage_1()
|
|
procedure to only allow root users to print a message to the console.
|
|
.ID
|
|
int *
|
|
printmessage_1(msg, rq)
|
|
char **msg;
|
|
struct svc_req *rq;
|
|
{
|
|
static in result; /* \fIMust be static\fP */
|
|
FILE *f;
|
|
struct suthunix_parms *aup;
|
|
.sp .5
|
|
aup = (struct authunix_parms *)rq->rq_clntcred;
|
|
if (aup->aup_uid != 0) {
|
|
result = 0;
|
|
return (&result);
|
|
}
|
|
.sp
|
|
.ft I
|
|
/*
|
|
* Same code as before.
|
|
*/
|
|
.ft L
|
|
}
|
|
.DE
|
|
.NH 1
|
|
\&RPC Language
|
|
.IX RPCL
|
|
.IX rpcgen "RPC Language" \fIrpcgen\fP
|
|
.LP
|
|
RPC language is an extension of XDR language. The sole extension is
|
|
the addition of the
|
|
.I program
|
|
type. For a complete description of the XDR language syntax, see the
|
|
.I "External Data Representation Standard: Protocol Specification"
|
|
chapter. For a description of the RPC extensions to the XDR language,
|
|
see the
|
|
.I "Remote Procedure Calls: Protocol Specification"
|
|
chapter.
|
|
.LP
|
|
However, XDR language is so close to C that if you know C, you know most
|
|
of it already. We describe here the syntax of the RPC language,
|
|
showing a few examples along the way. We also show how the various
|
|
RPC and XDR type definitions get compiled into C type definitions in
|
|
the output header file.
|
|
.KS
|
|
.NH 2
|
|
Definitions
|
|
\&
|
|
.IX rpcgen definitions \fIrpcgen\fP
|
|
.LP
|
|
An RPC language file consists of a series of definitions.
|
|
.DS L
|
|
.ft CW
|
|
definition-list:
|
|
definition ";"
|
|
definition ";" definition-list
|
|
.DE
|
|
.KE
|
|
It recognizes five types of definitions.
|
|
.DS L
|
|
.ft CW
|
|
definition:
|
|
enum-definition
|
|
struct-definition
|
|
union-definition
|
|
typedef-definition
|
|
const-definition
|
|
program-definition
|
|
.DE
|
|
.NH 2
|
|
Structures
|
|
\&
|
|
.IX rpcgen structures \fIrpcgen\fP
|
|
.LP
|
|
An XDR struct is declared almost exactly like its C counterpart. It
|
|
looks like the following:
|
|
.DS L
|
|
.ft CW
|
|
struct-definition:
|
|
"struct" struct-ident "{"
|
|
declaration-list
|
|
"}"
|
|
|
|
declaration-list:
|
|
declaration ";"
|
|
declaration ";" declaration-list
|
|
.DE
|
|
As an example, here is an XDR structure to a two-dimensional
|
|
coordinate, and the C structure that it gets compiled into in the
|
|
output header file.
|
|
.DS
|
|
.ft CW
|
|
struct coord { struct coord {
|
|
int x; --> int x;
|
|
int y; int y;
|
|
}; };
|
|
typedef struct coord coord;
|
|
.DE
|
|
The output is identical to the input, except for the added
|
|
.I typedef
|
|
at the end of the output. This allows one to use \*Qcoord\*U instead of
|
|
\*Qstruct coord\*U when declaring items.
|
|
.NH 2
|
|
Unions
|
|
\&
|
|
.IX rpcgen unions \fIrpcgen\fP
|
|
.LP
|
|
XDR unions are discriminated unions, and look quite different from C
|
|
unions. They are more analogous to Pascal variant records than they
|
|
are to C unions.
|
|
.DS L
|
|
.ft CW
|
|
union-definition:
|
|
"union" union-ident "switch" "(" declaration ")" "{"
|
|
case-list
|
|
"}"
|
|
|
|
case-list:
|
|
"case" value ":" declaration ";"
|
|
"default" ":" declaration ";"
|
|
"case" value ":" declaration ";" case-list
|
|
.DE
|
|
Here is an example of a type that might be returned as the result of a
|
|
\*Qread data\*U operation. If there is no error, return a block of data.
|
|
Otherwise, don't return anything.
|
|
.DS L
|
|
.ft CW
|
|
union read_result switch (int errno) {
|
|
case 0:
|
|
opaque data[1024];
|
|
default:
|
|
void;
|
|
};
|
|
.DE
|
|
It gets compiled into the following:
|
|
.DS L
|
|
.ft CW
|
|
struct read_result {
|
|
int errno;
|
|
union {
|
|
char data[1024];
|
|
} read_result_u;
|
|
};
|
|
typedef struct read_result read_result;
|
|
.DE
|
|
Notice that the union component of the output struct has the name as
|
|
the type name, except for the trailing \*Q_u\*U.
|
|
.NH 2
|
|
Enumerations
|
|
\&
|
|
.IX rpcgen enumerations \fIrpcgen\fP
|
|
.LP
|
|
XDR enumerations have the same syntax as C enumerations.
|
|
.DS L
|
|
.ft CW
|
|
enum-definition:
|
|
"enum" enum-ident "{"
|
|
enum-value-list
|
|
"}"
|
|
|
|
enum-value-list:
|
|
enum-value
|
|
enum-value "," enum-value-list
|
|
|
|
enum-value:
|
|
enum-value-ident
|
|
enum-value-ident "=" value
|
|
.DE
|
|
Here is a short example of an XDR enum, and the C enum that it gets
|
|
compiled into.
|
|
.DS L
|
|
.ft CW
|
|
enum colortype { enum colortype {
|
|
RED = 0, RED = 0,
|
|
GREEN = 1, --> GREEN = 1,
|
|
BLUE = 2 BLUE = 2,
|
|
}; };
|
|
typedef enum colortype colortype;
|
|
.DE
|
|
.NH 2
|
|
Typedef
|
|
\&
|
|
.IX rpcgen typedef \fIrpcgen\fP
|
|
.LP
|
|
XDR typedefs have the same syntax as C typedefs.
|
|
.DS L
|
|
.ft CW
|
|
typedef-definition:
|
|
"typedef" declaration
|
|
.DE
|
|
Here is an example that defines a
|
|
.I fname_type
|
|
used for declaring
|
|
file name strings that have a maximum length of 255 characters.
|
|
.DS L
|
|
.ft CW
|
|
typedef string fname_type<255>; --> typedef char *fname_type;
|
|
.DE
|
|
.NH 2
|
|
Constants
|
|
\&
|
|
.IX rpcgen constants \fIrpcgen\fP
|
|
.LP
|
|
XDR constants symbolic constants that may be used wherever a
|
|
integer constant is used, for example, in array size specifications.
|
|
.DS L
|
|
.ft CW
|
|
const-definition:
|
|
"const" const-ident "=" integer
|
|
.DE
|
|
For example, the following defines a constant
|
|
.I DOZEN
|
|
equal to 12.
|
|
.DS L
|
|
.ft CW
|
|
const DOZEN = 12; --> #define DOZEN 12
|
|
.DE
|
|
.NH 2
|
|
Programs
|
|
\&
|
|
.IX rpcgen programs \fIrpcgen\fP
|
|
.LP
|
|
RPC programs are declared using the following syntax:
|
|
.DS L
|
|
.ft CW
|
|
program-definition:
|
|
"program" program-ident "{"
|
|
version-list
|
|
"}" "=" value
|
|
|
|
version-list:
|
|
version ";"
|
|
version ";" version-list
|
|
|
|
version:
|
|
"version" version-ident "{"
|
|
procedure-list
|
|
"}" "=" value
|
|
|
|
procedure-list:
|
|
procedure ";"
|
|
procedure ";" procedure-list
|
|
|
|
procedure:
|
|
type-ident procedure-ident "(" type-ident ")" "=" value
|
|
.DE
|
|
For example, here is the time protocol, revisited:
|
|
.ie t .DS
|
|
.el .DS L
|
|
.ft I
|
|
/*
|
|
* time.x: Get or set the time. Time is represented as number of seconds
|
|
* since 0:00, January 1, 1970.
|
|
*/
|
|
.ft CW
|
|
program TIMEPROG {
|
|
version TIMEVERS {
|
|
unsigned int TIMEGET(void) = 1;
|
|
void TIMESET(unsigned) = 2;
|
|
} = 1;
|
|
} = 44;
|
|
.DE
|
|
This file compiles into #defines in the output header file:
|
|
.ie t .DS
|
|
.el .DS L
|
|
.ft CW
|
|
#define TIMEPROG 44
|
|
#define TIMEVERS 1
|
|
#define TIMEGET 1
|
|
#define TIMESET 2
|
|
.DE
|
|
.NH 2
|
|
Declarations
|
|
\&
|
|
.IX rpcgen declarations \fIrpcgen\fP
|
|
.LP
|
|
In XDR, there are only four kinds of declarations.
|
|
.DS L
|
|
.ft CW
|
|
declaration:
|
|
simple-declaration
|
|
fixed-array-declaration
|
|
variable-array-declaration
|
|
pointer-declaration
|
|
.DE
|
|
\fB1) Simple declarations\fP are just like simple C declarations.
|
|
.DS L
|
|
.ft CW
|
|
simple-declaration:
|
|
type-ident variable-ident
|
|
.DE
|
|
Example:
|
|
.DS L
|
|
.ft CW
|
|
colortype color; --> colortype color;
|
|
.DE
|
|
\fB2) Fixed-length Array Declarations\fP are just like C array declarations:
|
|
.DS L
|
|
.ft CW
|
|
fixed-array-declaration:
|
|
type-ident variable-ident "[" value "]"
|
|
.DE
|
|
Example:
|
|
.DS L
|
|
.ft CW
|
|
colortype palette[8]; --> colortype palette[8];
|
|
.DE
|
|
\fB3) Variable-Length Array Declarations\fP have no explicit syntax
|
|
in C, so XDR invents its own using angle-brackets.
|
|
.DS L
|
|
.ft CW
|
|
variable-array-declaration:
|
|
type-ident variable-ident "<" value ">"
|
|
type-ident variable-ident "<" ">"
|
|
.DE
|
|
The maximum size is specified between the angle brackets. The size may
|
|
be omitted, indicating that the array may be of any size.
|
|
.DS L
|
|
.ft CW
|
|
int heights<12>; /* \fIat most 12 items\fP */
|
|
int widths<>; /* \fIany number of items\fP */
|
|
.DE
|
|
Since variable-length arrays have no explicit syntax in C, these
|
|
declarations are actually compiled into \*Qstruct\*Us. For example, the
|
|
\*Qheights\*U declaration gets compiled into the following struct:
|
|
.DS L
|
|
.ft CW
|
|
struct {
|
|
u_int heights_len; /* \fI# of items in array\fP */
|
|
int *heights_val; /* \fIpointer to array\fP */
|
|
} heights;
|
|
.DE
|
|
Note that the number of items in the array is stored in the \*Q_len\*U
|
|
component and the pointer to the array is stored in the \*Q_val\*U
|
|
component. The first part of each of these component's names is the
|
|
same as the name of the declared XDR variable.
|
|
.LP
|
|
\fB4) Pointer Declarations\fP are made in
|
|
XDR exactly as they are in C. You can't
|
|
really send pointers over the network, but you can use XDR pointers
|
|
for sending recursive data types such as lists and trees. The type is
|
|
actually called \*Qoptional-data\*U, not \*Qpointer\*U, in XDR language.
|
|
.DS L
|
|
.ft CW
|
|
pointer-declaration:
|
|
type-ident "*" variable-ident
|
|
.DE
|
|
Example:
|
|
.DS L
|
|
.ft CW
|
|
listitem *next; --> listitem *next;
|
|
.DE
|
|
.NH 2
|
|
\&Special Cases
|
|
.IX rpcgen "special cases" \fIrpcgen\fP
|
|
.LP
|
|
There are a few exceptions to the rules described above.
|
|
.LP
|
|
.B Booleans:
|
|
C has no built-in boolean type. However, the RPC library does a
|
|
boolean type called
|
|
.I bool_t
|
|
that is either
|
|
.I TRUE
|
|
or
|
|
.I FALSE .
|
|
Things declared as type
|
|
.I bool
|
|
in XDR language are compiled into
|
|
.I bool_t
|
|
in the output header file.
|
|
.LP
|
|
Example:
|
|
.DS L
|
|
.ft CW
|
|
bool married; --> bool_t married;
|
|
.DE
|
|
.B Strings:
|
|
C has no built-in string type, but instead uses the null-terminated
|
|
\*Qchar *\*U convention. In XDR language, strings are declared using the
|
|
\*Qstring\*U keyword, and compiled into \*Qchar *\*Us in the output header
|
|
file. The maximum size contained in the angle brackets specifies the
|
|
maximum number of characters allowed in the strings (not counting the
|
|
.I NULL
|
|
character). The maximum size may be left off, indicating a string
|
|
of arbitrary length.
|
|
.LP
|
|
Examples:
|
|
.DS L
|
|
.ft CW
|
|
string name<32>; --> char *name;
|
|
string longname<>; --> char *longname;
|
|
.DE
|
|
.B "Opaque Data:"
|
|
Opaque data is used in RPC and XDR to describe untyped data, that is,
|
|
just sequences of arbitrary bytes. It may be declared either as a
|
|
fixed or variable length array.
|
|
.DS L
|
|
Examples:
|
|
.ft CW
|
|
opaque diskblock[512]; --> char diskblock[512];
|
|
|
|
opaque filedata<1024>; --> struct {
|
|
u_int filedata_len;
|
|
char *filedata_val;
|
|
} filedata;
|
|
.DE
|
|
.B Voids:
|
|
In a void declaration, the variable is not named. The declaration is
|
|
just \*Qvoid\*U and nothing else. Void declarations can only occur in two
|
|
places: union definitions and program definitions (as the argument or
|
|
result of a remote procedure).
|