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.ds RH "Advanced Topics
.bp .nr H1 5 .nr H2 0

5. ADVANCED TOPICS .R

A number of facilities have yet to be discussed. For most users of the IPC the mechanisms already described will suffice in constructing distributed applications. However, others will find the need to utilize some of the features which we consider in this section. Out of band data

The stream socket abstraction includes the notion of \*(lqout of band\*(rq data. Out of band data is a logically independent transmission channel associated with each pair of connected stream sockets. Out of band data is delivered to the user independently of normal data. The abstraction defines that the out of band data facilities must support the reliable delivery of at least one out of band message at a time. This message may contain at least one byte of data, and at least one message may be pending delivery to the user at any one time. For communications protocols which support only in-band signaling (i.e. the urgent data is delivered in sequence with the normal data), the system normally extracts the data from the normal data stream and stores it separately. This allows users to choose between receiving the urgent data in order and receiving it out of sequence without having to buffer all the intervening data. It is possible to ``peek'' (via MSG_PEEK) at out of band data. If the socket has a process group, a SIGURG signal is generated when the protocol is notified of its existence. A process can set the process group or process id to be informed by the SIGURG signal via the appropriate fcntl call, as described below for SIGIO. If multiple sockets may have out of band data awaiting delivery, a select call for exceptional conditions may be used to determine those sockets with such data pending. Neither the signal nor the select indicate the actual arrival of the out-of-band data, but only notification that it is pending.

In addition to the information passed, a logical mark is placed in the data stream to indicate the point at which the out of band data was sent. The remote login and remote shell applications use this facility to propagate signals between client and server processes. When a signal flushs any pending output from the remote process(es), all data up to the mark in the data stream is discarded.

To send an out of band message the MSG_OOB flag is supplied to a send or sendto calls, while to receive out of band data MSG_OOB should be indicated when performing a recvfrom or recv call. To find out if the read pointer is currently pointing at the mark in the data stream, the SIOCATMARK ioctl is provided: ioctl(s, SIOCATMARK, &yes); If yes is a 1 on return, the next read will return data after the mark. Otherwise (assuming out of band data has arrived), the next read will provide data sent by the client prior to transmission of the out of band signal. The routine used in the remote login process to flush output on receipt of an interrupt or quit signal is shown in Figure 5. It reads the normal data up to the mark (to discard it), then reads the out-of-band byte. .KF #include <sys/ioctl.h> #include <sys/file.h> ... oob() { int out = FWRITE, mark; char waste[BUFSIZ]; /* flush local terminal output */ ioctl(1, TIOCFLUSH, (char *)&out); for (;;) { if (ioctl(rem, SIOCATMARK, &mark) < 0) { perror("ioctl"); break; } if (mark) break; (void) read(rem, waste, sizeof (waste)); } if (recv(rem, &mark, 1, MSG_OOB) < 0) { perror("recv"); ... } ... }

Figure 5. Flushing terminal I/O on receipt of out of band data. .KE

A process may also read or peek at the out-of-band data without first reading up to the mark. This is more difficult when the underlying protocol delivers the urgent data in-band with the normal data, and only sends notification of its presence ahead of time (e.g., the TCP protocol used to implement streams in the Internet domain). With such protocols, the out-of-band byte may not yet have arrived when a recv is done with the MSG_OOB flag. In that case, the call will return an error of EWOULDBLOCK. Worse, there may be enough in-band data in the input buffer that normal flow control prevents the peer from sending the urgent data until the buffer is cleared. The process must then read enough of the queued data that the urgent data may be delivered.

Certain programs that use multiple bytes of urgent data and must handle multiple urgent signals (e.g., telnet\|(1C)) need to retain the position of urgent data within the stream. This treatment is available as a socket-level option, SO_OOBINLINE; see setsockopt\|(2) for usage. With this option, the position of urgent data (the \*(lqmark\*(rq) is retained, but the urgent data immediately follows the mark within the normal data stream returned without the MSG_OOB flag. Reception of multiple urgent indications causes the mark to move, but no out-of-band data are lost. Non-Blocking Sockets

It is occasionally convenient to make use of sockets which do not block; that is, I/O requests which cannot complete immediately and would therefore cause the process to be suspended awaiting completion are not executed, and an error code is returned. Once a socket has been created via the socket call, it may be marked as non-blocking by fcntl as follows: #include <fcntl.h> ... int s; ... s = socket(AF_INET, SOCK_STREAM, 0); ... if (fcntl(s, F_SETFL, FNDELAY) < 0) perror("fcntl F_SETFL, FNDELAY"); exit(1); } ...

When performing non-blocking I/O on sockets, one must be careful to check for the error EWOULDBLOCK (stored in the global variable errno), which occurs when an operation would normally block, but the socket it was performed on is marked as non-blocking. In particular, accept, connect, send, recv, read, and write can all return EWOULDBLOCK, and processes should be prepared to deal with such return codes. If an operation such as a send cannot be done in its entirety, but partial writes are sensible (for example, when using a stream socket), the data that can be sent immediately will be processed, and the return value will indicate the amount actually sent. Interrupt driven socket I/O

The SIGIO signal allows a process to be notified via a signal when a socket (or more generally, a file descriptor) has data waiting to be read. Use of the SIGIO facility requires three steps: First, the process must set up a SIGIO signal handler by use of the signal or sigvec calls. Second, it must set the process id or process group id which is to receive notification of pending input to its own process id, or the process group id of its process group (note that the default process group of a socket is group zero). This is accomplished by use of an fcntl call. Third, it must enable asynchronous notification of pending I/O requests with another fcntl call. Sample code to allow a given process to receive information on pending I/O requests as they occur for a socket s is given in Figure 6. With the addition of a handler for SIGURG, this code can also be used to prepare for receipt of SIGURG signals. .KF #include <fcntl.h> ... int io_handler(); ... signal(SIGIO, io_handler); /* Set the process receiving SIGIO/SIGURG signals to us */ if (fcntl(s, F_SETOWN, getpid()) < 0) { perror("fcntl F_SETOWN"); exit(1); } /* Allow receipt of asynchronous I/O signals */ if (fcntl(s, F_SETFL, FASYNC) < 0) { perror("fcntl F_SETFL, FASYNC"); exit(1); }

Figure 6. Use of asynchronous notification of I/O requests. .KE Signals and process groups

Due to the existence of the SIGURG and SIGIO signals each socket has an associated process number, just as is done for terminals. This value is initialized to zero, but may be redefined at a later time with the F_SETOWN fcntl, such as was done in the code above for SIGIO. To set the socket's process id for signals, positive arguments should be given to the fcntl call. To set the socket's process group for signals, negative arguments should be passed to fcntl. Note that the process number indicates either the associated process id or the associated process group; it is impossible to specify both at the same time. A similar fcntl, F_GETOWN, is available for determining the current process number of a socket.

Another signal which is useful when constructing server processes is SIGCHLD. This signal is delivered to a process when any child processes have changed state. Normally servers use the signal to \*(lqreap\*(rq child processes that have exited without explicitly awaiting their termination or periodic polling for exit status. For example, the remote login server loop shown in Figure 2 may be augmented as shown in Figure 7. .KF int reaper(); ... signal(SIGCHLD, reaper); listen(f, 5); for (;;) { int g, len = sizeof (from); g = accept(f, (struct sockaddr *)&from, &len,); if (g < 0) { if (errno != EINTR) syslog(LOG_ERR, "rlogind: accept: %m"); continue; } ... } ... #include <wait.h> reaper() { union wait status; while (wait3(&status, WNOHANG, 0) > 0) ; }

Figure 7. Use of the SIGCHLD signal. .KE

If the parent server process fails to reap its children, a large number of \*(lqzombie\*(rq processes may be created. Pseudo terminals

Many programs will not function properly without a terminal for standard input and output. Since sockets do not provide the semantics of terminals, it is often necessary to have a process communicating over the network do so through a pseudo-terminal. A pseudo- terminal is actually a pair of devices, master and slave, which allow a process to serve as an active agent in communication between processes and users. Data written on the slave side of a pseudo-terminal is supplied as input to a process reading from the master side, while data written on the master side are processed as terminal input for the slave. In this way, the process manipulating the master side of the pseudo-terminal has control over the information read and written on the slave side as if it were manipulating the keyboard and reading the screen on a real terminal. The purpose of this abstraction is to preserve terminal semantics over a network connection\(em that is, the slave side appears as a normal terminal to any process reading from or writing to it.

For example, the remote login server uses pseudo-terminals for remote login sessions. A user logging in to a machine across the network is provided a shell with a slave pseudo-terminal as standard input, output, and error. The server process then handles the communication between the programs invoked by the remote shell and the user's local client process. When a user sends a character that generates an interrupt on the remote machine that flushes terminal output, the pseudo-terminal generates a control message for the server process. The server then sends an out of band message to the client process to signal a flush of data at the real terminal and on the intervening data buffered in the network.

Under 4.4BSD, the name of the slave side of a pseudo-terminal is of the form /dev/ttyxy, where x is a single letter starting at `p' and continuing to `t'. y is a hexadecimal digit (i.e., a single character in the range 0 through 9 or `a' through `f'). The master side of a pseudo-terminal is /dev/ptyxy, where x and y correspond to the slave side of the pseudo-terminal.

In general, the method of obtaining a pair of master and slave pseudo-terminals is to find a pseudo-terminal which is not currently in use. The master half of a pseudo-terminal is a single-open device; thus, each master may be opened in turn until an open succeeds. The slave side of the pseudo-terminal is then opened, and is set to the proper terminal modes if necessary. The process then forks; the child closes the master side of the pseudo-terminal, and execs the appropriate program. Meanwhile, the parent closes the slave side of the pseudo-terminal and begins reading and writing from the master side. Sample code making use of pseudo-terminals is given in Figure 8; this code assumes that a connection on a socket s exists, connected to a peer who wants a service of some kind, and that the process has disassociated itself from any previous controlling terminal. .KF gotpty = 0; for (c = 'p'; !gotpty && c <= 's'; c++) { line = "/dev/ptyXX"; line[sizeof("/dev/pty")-1] = c; line[sizeof("/dev/ptyp")-1] = '0'; if (stat(line, &statbuf) < 0) break; for (i = 0; i < 16; i++) { line[sizeof("/dev/ptyp")-1] = "0123456789abcdef"[i]; master = open(line, O_RDWR); if (master > 0) { gotpty = 1; break; } } } if (!gotpty) { syslog(LOG_ERR, "All network ports in use"); exit(1); } line[sizeof("/dev/")-1] = 't'; slave = open(line, O_RDWR); /* slave is now slave side */ if (slave < 0) { syslog(LOG_ERR, "Cannot open slave pty %s", line); exit(1); } ioctl(slave, TIOCGETP, &b); /* Set slave tty modes */ b.sg_flags = CRMOD|XTABS|ANYP; ioctl(slave, TIOCSETP, &b); i = fork(); if (i < 0) { syslog(LOG_ERR, "fork: %m"); exit(1); } else if (i) { /* Parent */ close(slave); ... } else { /* Child */ (void) close(s); (void) close(master); dup2(slave, 0); dup2(slave, 1); dup2(slave, 2); if (slave > 2) (void) close(slave); ... }

Figure 8. Creation and use of a pseudo terminal .KE Selecting specific protocols

If the third argument to the socket call is 0, socket will select a default protocol to use with the returned socket of the type requested. The default protocol is usually correct, and alternate choices are not usually available. However, when using ``raw'' sockets to communicate directly with lower-level protocols or hardware interfaces, the protocol argument may be important for setting up demultiplexing. For example, raw sockets in the Internet family may be used to implement a new protocol above IP, and the socket will receive packets only for the protocol specified. To obtain a particular protocol one determines the protocol number as defined within the communication domain. For the Internet domain one may use one of the library routines discussed in section 3, such as getprotobyname: #include <sys/types.h> #include <sys/socket.h> #include <netinet/in.h> #include <netdb.h> ... pp = getprotobyname("newtcp"); s = socket(AF_INET, SOCK_STREAM, pp->p_proto); This would result in a socket s using a stream based connection, but with protocol type of ``newtcp'' instead of the default ``tcp.''

In the NS domain, the available socket protocols are defined in <netns/ns.h>. To create a raw socket for Xerox Error Protocol messages, one might use: #include <sys/types.h> #include <sys/socket.h> #include <netns/ns.h> ... s = socket(AF_NS, SOCK_RAW, NSPROTO_ERROR); Address binding

As was mentioned in section 2, binding addresses to sockets in the Internet and NS domains can be fairly complex. As a brief reminder, these associations are composed of local and foreign addresses, and local and foreign ports. Port numbers are allocated out of separate spaces, one for each system and one for each domain on that system. Through the bind system call, a process may specify half of an association, the <local address, local port> part, while the connect and accept primitives are used to complete a socket's association by specifying the <foreign address, foreign port> part. Since the association is created in two steps the association uniqueness requirement indicated previously could be violated unless care is taken. Further, it is unrealistic to expect user programs to always know proper values to use for the local address and local port since a host may reside on multiple networks and the set of allocated port numbers is not directly accessible to a user.

To simplify local address binding in the Internet domain the notion of a \*(lqwildcard\*(rq address has been provided. When an address is specified as INADDR_ANY (a manifest constant defined in <netinet/in.h>), the system interprets the address as \*(lqany valid address\*(rq. For example, to bind a specific port number to a socket, but leave the local address unspecified, the following code might be used: #include <sys/types.h> #include <netinet/in.h> ... struct sockaddr_in sin; ... s = socket(AF_INET, SOCK_STREAM, 0); sin.sin_family = AF_INET; sin.sin_addr.s_addr = htonl(INADDR_ANY); sin.sin_port = htons(MYPORT); bind(s, (struct sockaddr *) &sin, sizeof (sin)); Sockets with wildcarded local addresses may receive messages directed to the specified port number, and sent to any of the possible addresses assigned to a host. For example, if a host has addresses 128.32.0.4 and 10.0.0.78, and a socket is bound as above, the process will be able to accept connection requests which are addressed to 128.32.0.4 or 10.0.0.78. If a server process wished to only allow hosts on a given network connect to it, it would bind the address of the host on the appropriate network.

In a similar fashion, a local port may be left unspecified (specified as zero), in which case the system will select an appropriate port number for it. This shortcut will work both in the Internet and NS domains. For example, to bind a specific local address to a socket, but to leave the local port number unspecified: hp = gethostbyname(hostname); if (hp == NULL) { ... } bcopy(hp->h_addr, (char *) sin.sin_addr, hp->h_length); sin.sin_port = htons(0); bind(s, (struct sockaddr *) &sin, sizeof (sin)); The system selects the local port number based on two criteria. The first is that on 4BSD systems, Internet ports below IPPORT_RESERVED (1024) (for the Xerox domain, 0 through 3000) are reserved for privileged users (i.e., the super user); Internet ports above IPPORT_USERRESERVED (50000) are reserved for non-privileged servers. The second is that the port number is not currently bound to some other socket. In order to find a free Internet port number in the privileged range the rresvport library routine may be used as follows to return a stream socket in with a privileged port number: int lport = IPPORT_RESERVED - 1; int s; ... s = rresvport(&lport); if (s < 0) { if (errno == EAGAIN) fprintf(stderr, "socket: all ports in use\en"); else perror("rresvport: socket"); ... } The restriction on allocating ports was done to allow processes executing in a \*(lqsecure\*(rq environment to perform authentication based on the originating address and port number. For example, the rlogin(1) command allows users to log in across a network without being asked for a password, if two conditions hold: First, the name of the system the user is logging in from is in the file /etc/hosts.equiv on the system he is logging in to (or the system name and the user name are in the user's .rhosts file in the user's home directory), and second, that the user's rlogin process is coming from a privileged port on the machine from which he is logging. The port number and network address of the machine from which the user is logging in can be determined either by the from result of the accept call, or from the getpeername call.

In certain cases the algorithm used by the system in selecting port numbers is unsuitable for an application. This is because associations are created in a two step process. For example, the Internet file transfer protocol, FTP, specifies that data connections must always originate from the same local port. However, duplicate associations are avoided by connecting to different foreign ports. In this situation the system would disallow binding the same local address and port number to a socket if a previous data connection's socket still existed. To override the default port selection algorithm, an option call must be performed prior to address binding: ... int on = 1; ... setsockopt(s, SOL_SOCKET, SO_REUSEADDR, &on, sizeof(on)); bind(s, (struct sockaddr *) &sin, sizeof (sin)); With the above call, local addresses may be bound which are already in use. This does not violate the uniqueness requirement as the system still checks at connect time to be sure any other sockets with the same local address and port do not have the same foreign address and port. If the association already exists, the error EADDRINUSE is returned. A related socket option, SO_REUSEPORT, which allows completely duplicate bindings, is described in the IP multicasting section. Socket Options

It is possible to set and get a number of options on sockets via the setsockopt and getsockopt system calls. These options include such things as marking a socket for broadcasting, not to route, to linger on close, etc. In addition, there are protocol-specific options for IP and TCP, as described in ip (4), tcp (4), and in the section on multicasting below.

The general forms of the calls are: setsockopt(s, level, optname, optval, optlen); and getsockopt(s, level, optname, optval, optlen);

The parameters to the calls are as follows: s is the socket on which the option is to be applied. Level specifies the protocol layer on which the option is to be applied; in most cases this is the ``socket level'', indicated by the symbolic constant SOL_SOCKET, defined in <sys/socket.h>. The actual option is specified in optname, and is a symbolic constant also defined in <sys/socket.h>. Optval and Optlen point to the value of the option (in most cases, whether the option is to be turned on or off), and the length of the value of the option, respectively. For getsockopt, optlen is a value-result parameter, initially set to the size of the storage area pointed to by optval, and modified upon return to indicate the actual amount of storage used.

An example should help clarify things. It is sometimes useful to determine the type (e.g., stream, datagram, etc.) of an existing socket; programs under inetd (described below) may need to perform this task. This can be accomplished as follows via the SO_TYPE socket option and the getsockopt call: #include <sys/types.h> #include <sys/socket.h> int type, size; size = sizeof (int); if (getsockopt(s, SOL_SOCKET, SO_TYPE, (char *) &type, &size) < 0) { ... } After the getsockopt call, type will be set to the value of the socket type, as defined in <sys/socket.h>. If, for example, the socket were a datagram socket, type would have the value corresponding to SOCK_DGRAM. Broadcasting and determining network configuration

By using a datagram socket, it is possible to send broadcast packets on many networks supported by the system. The network itself must support broadcast; the system provides no simulation of broadcast in software. Broadcast messages can place a high load on a network since they force every host on the network to service them. Consequently, the ability to send broadcast packets has been limited to sockets which are explicitly marked as allowing broadcasting. Broadcast is typically used for one of two reasons: it is desired to find a resource on a local network without prior knowledge of its address, or important functions such as routing require that information be sent to all accessible neighbors.

Multicasting is an alternative to broadcasting. Setting up IP multicast sockets is described in the next section.

To send a broadcast message, a datagram socket should be created: s = socket(AF_INET, SOCK_DGRAM, 0); or s = socket(AF_NS, SOCK_DGRAM, 0); The socket is marked as allowing broadcasting, int on = 1; setsockopt(s, SOL_SOCKET, SO_BROADCAST, &on, sizeof (on)); and at least a port number should be bound to the socket: sin.sin_family = AF_INET; sin.sin_addr.s_addr = htonl(INADDR_ANY); sin.sin_port = htons(MYPORT); bind(s, (struct sockaddr *) &sin, sizeof (sin)); or, for the NS domain, sns.sns_family = AF_NS; netnum = htonl(net); sns.sns_addr.x_net = *(union ns_net *) &netnum; /* insert net number */ sns.sns_addr.x_port = htons(MYPORT); bind(s, (struct sockaddr *) &sns, sizeof (sns)); The destination address of the message to be broadcast depends on the network(s) on which the message is to be broadcast. The Internet domain supports a shorthand notation for broadcast on the local network, the address INADDR_BROADCAST (defined in <netinet/in.h>. To determine the list of addresses for all reachable neighbors requires knowledge of the networks to which the host is connected. Since this information should be obtained in a host-independent fashion and may be impossible to derive, 4.4BSD provides a method of retrieving this information from the system data structures. The SIOCGIFCONF ioctl call returns the interface configuration of a host in the form of a single ifconf structure; this structure contains a ``data area'' which is made up of an array of of ifreq structures, one for each network interface to which the host is connected. These structures are defined in <net/if.h> as follows: struct ifconf { int ifc_len; /* size of associated buffer */ union { caddr_t ifcu_buf; struct ifreq *ifcu_req; } ifc_ifcu; }; #define ifc_buf ifc_ifcu.ifcu_buf /* buffer address */ #define ifc_req ifc_ifcu.ifcu_req /* array of structures returned */ #define IFNAMSIZ 16 struct ifreq { char ifr_name[IFNAMSIZ]; /* if name, e.g. "en0" */ union { struct sockaddr ifru_addr; struct sockaddr ifru_dstaddr; struct sockaddr ifru_broadaddr; short ifru_flags; caddr_t ifru_data; } ifr_ifru; }; #define ifr_addr ifr_ifru.ifru_addr /* address */ #define ifr_dstaddr ifr_ifru.ifru_dstaddr /* other end of p-to-p link */ #define ifr_broadaddr ifr_ifru.ifru_broadaddr /* broadcast address */ #define ifr_flags ifr_ifru.ifru_flags /* flags */ #define ifr_data ifr_ifru.ifru_data /* for use by interface */ The actual call which obtains the interface configuration is struct ifconf ifc; char buf[BUFSIZ]; ifc.ifc_len = sizeof (buf); ifc.ifc_buf = buf; if (ioctl(s, SIOCGIFCONF, (char *) &ifc) < 0) { ... } After this call buf will contain one ifreq structure for each network to which the host is connected, and ifc.ifc_len will have been modified to reflect the number of bytes used by the ifreq structures.

For each structure there exists a set of ``interface flags'' which tell whether the network corresponding to that interface is up or down, point to point or broadcast, etc. The SIOCGIFFLAGS ioctl retrieves these flags for an interface specified by an ifreq structure as follows: struct ifreq *ifr; ifr = ifc.ifc_req; for (n = ifc.ifc_len / sizeof (struct ifreq); --n >= 0; ifr++) { /* * We must be careful that we don't use an interface * devoted to an address family other than those intended; * if we were interested in NS interfaces, the * AF_INET would be AF_NS. */ if (ifr->ifr_addr.sa_family != AF_INET) continue; if (ioctl(s, SIOCGIFFLAGS, (char *) ifr) < 0) { ... } /* * Skip boring cases. */ if ((ifr->ifr_flags & IFF_UP) == 0 || (ifr->ifr_flags & IFF_LOOPBACK) || (ifr->ifr_flags & (IFF_BROADCAST | IFF_POINTTOPOINT)) == 0) continue;

Once the flags have been obtained, the broadcast address must be obtained. In the case of broadcast networks this is done via the SIOCGIFBRDADDR ioctl, while for point-to-point networks the address of the destination host is obtained with SIOCGIFDSTADDR. struct sockaddr dst; if (ifr->ifr_flags & IFF_POINTTOPOINT) { if (ioctl(s, SIOCGIFDSTADDR, (char *) ifr) < 0) { ... } bcopy((char *) ifr->ifr_dstaddr, (char *) &dst, sizeof (ifr->ifr_dstaddr)); } else if (ifr->ifr_flags & IFF_BROADCAST) { if (ioctl(s, SIOCGIFBRDADDR, (char *) ifr) < 0) { ... } bcopy((char *) ifr->ifr_broadaddr, (char *) &dst, sizeof (ifr->ifr_broadaddr)); }

After the appropriate ioctl's have obtained the broadcast or destination address (now in dst), the sendto call may be used: sendto(s, buf, buflen, 0, (struct sockaddr *)&dst, sizeof (dst)); } In the above loop one sendto occurs for every interface to which the host is connected that supports the notion of broadcast or point-to-point addressing. If a process only wished to send broadcast messages on a given network, code similar to that outlined above would be used, but the loop would need to find the correct destination address.

Received broadcast messages contain the senders address and port, as datagram sockets are bound before a message is allowed to go out. IP Multicasting

IP multicasting is the transmission of an IP datagram to a "host group", a set of zero or more hosts identified by a single IP destination address. A multicast datagram is delivered to all members of its destination host group with the same "best-efforts" reliability as regular unicast IP datagrams, i.e., the datagram is not guaranteed to arrive intact at all members of the destination group or in the same order relative to other datagrams.

The membership of a host group is dynamic; that is, hosts may join and leave groups at any time. There is no restriction on the location or number of members in a host group. A host may be a member of more than one group at a time. A host need not be a member of a group to send datagrams to it.

A host group may be permanent or transient. A permanent group has a well-known, administratively assigned IP address. It is the address, not the membership of the group, that is permanent; at any time a permanent group may have any number of members, even zero. Those IP multicast addresses that are not reserved for permanent groups are available for dynamic assignment to transient groups which exist only as long as they have members.

In general, a host cannot assume that datagrams sent to any host group address will reach only the intended hosts, or that datagrams received as a member of a transient host group are intended for the recipient. Misdelivery must be detected at a level above IP, using higher-level identifiers or authentication tokens. Information transmitted to a host group address should be encrypted or governed by administrative routing controls if the sender is concerned about unwanted listeners.

IP multicasting is currently supported only on AF_INET sockets of type SOCK_DGRAM and SOCK_RAW, and only on subnetworks for which the interface driver has been modified to support multicasting.

The next subsections describe how to send and receive multicast datagrams. Sending IP Multicast Datagrams

To send a multicast datagram, specify an IP multicast address in the range 224.0.0.0 to 239.255.255.255 as the destination address in a sendto (2) call.

The definitions required for the multicast-related socket options are found in <netinet/in.h>. All IP addresses are passed in network byte-order.

By default, IP multicast datagrams are sent with a time-to-live (TTL) of 1, which prevents them from being forwarded beyond a single subnetwork. A new socket option allows the TTL for subsequent multicast datagrams to be set to any value from 0 to 255, in order to control the scope of the multicasts: u_char ttl; setsockopt(sock, IPPROTO_IP, IP_MULTICAST_TTL, &ttl, sizeof(ttl)); Multicast datagrams with a TTL of 0 will not be transmitted on any subnet, but may be delivered locally if the sending host belongs to the destination group and if multicast loopback has not been disabled on the sending socket (see below). Multicast datagrams with TTL greater than one may be delivered to more than one subnet if there are one or more multicast routers attached to the first-hop subnet. To provide meaningful scope control, the multicast routers support the notion of TTL "thresholds", which prevent datagrams with less than a certain TTL from traversing certain subnets. The thresholds enforce the following convention:

Scope Initial TTL
restricted to the same host 0
restricted to the same subnet 1
restricted to the same site 32
restricted to the same region 64
restricted to the same continent 128
unrestricted 255
"Sites" and "regions" are not strictly defined, and sites may be further subdivided into smaller administrative units, as a local matter.

An application may choose an initial TTL other than the ones listed above. For example, an application might perform an "expanding-ring search" for a network resource by sending a multicast query, first with a TTL of 0, and then with larger and larger TTLs, until a reply is received, perhaps using the TTL sequence 0, 1, 2, 4, 8, 16, 32.

The multicast router mrouted (8), refuses to forward any multicast datagram with a destination address between 224.0.0.0 and 224.0.0.255, inclusive, regardless of its TTL. This range of addresses is reserved for the use of routing protocols and other low-level topology discovery or maintenance protocols, such as gateway discovery and group membership reporting.

The address 224.0.0.0 is guaranteed not to be assigned to any group, and 224.0.0.1 is assigned to the permanent group of all IP hosts (including gateways). This is used to address all multicast hosts on the directly connected network. There is no multicast address (or any other IP address) for all hosts on the total Internet. The addresses of other well-known, permanent groups are published in the "Assigned Numbers" RFC, which is available from the InterNIC.

Each multicast transmission is sent from a single network interface, even if the host has more than one multicast-capable interface. (If the host is also serving as a multicast router, a multicast may be forwarded to interfaces other than originating interface, provided that the TTL is greater than 1.) The default interface to be used for multicasting is the primary network interface on the system. A socket option is available to override the default for subsequent transmissions from a given socket: struct in_addr addr; setsockopt(sock, IPPROTO_IP, IP_MULTICAST_IF, &addr, sizeof(addr)); where "addr" is the local IP address of the desired outgoing interface. An address of INADDR_ANY may be used to revert to the default interface. The local IP address of an interface can be obtained via the SIOCGIFCONF ioctl. To determine if an interface supports multicasting, fetch the interface flags via the SIOCGIFFLAGS ioctl and see if the IFF_MULTICAST flag is set. (Normal applications should not need to use this option; it is intended primarily for multicast routers and other system services specifically concerned with internet topology.) The SIOCGIFCONF and SIOCGIFFLAGS ioctls are described in the previous section.

If a multicast datagram is sent to a group to which the sending host itself belongs (on the outgoing interface), a copy of the datagram is, by default, looped back by the IP layer for local delivery. Another socket option gives the sender explicit control over whether or not subsequent datagrams are looped back: u_char loop; setsockopt(sock, IPPROTO_IP, IP_MULTICAST_LOOP, &loop, sizeof(loop)); where \f2loop\f1 is set to 0 to disable loopback, and set to 1 to enable loopback. This option improves performance for applications that may have no more than one instance on a single host (such as a router demon), by eliminating the overhead of receiving their own transmissions. It should generally not be used by applications for which there may be more than one instance on a single host (such as a conferencing program) or for which the sender does not belong to the destination group (such as a time querying program).

A multicast datagram sent with an initial TTL greater than 1 may be delivered to the sending host on a different interface from that on which it was sent, if the host belongs to the destination group on that other interface. The loopback control option has no effect on such delivery. Receiving IP Multicast Datagrams

Before a host can receive IP multicast datagrams, it must become a member of one or more IP multicast groups. A process can ask the host to join a multicast group by using the following socket option: struct ip_mreq mreq; setsockopt(sock, IPPROTO_IP, IP_ADD_MEMBERSHIP, &mreq, sizeof(mreq)) where "mreq" is the following structure: struct ip_mreq { struct in_addr imr_multiaddr; /* multicast group to join */ struct in_addr imr_interface; /* interface to join on */ } Every membership is associated with a single interface, and it is possible to join the same group on more than one interface. "imr_interface" should be INADDR_ANY to choose the default multicast interface, or one of the host's local addresses to choose a particular (multicast-capable) interface. Up to IP_MAX_MEMBERSHIPS (currently 20) memberships may be added on a single socket.

To drop a membership, use: struct ip_mreq mreq; setsockopt(sock, IPPROTO_IP, IP_DROP_MEMBERSHIP, &mreq, sizeof(mreq)); where "mreq" contains the same values as used to add the membership. The memberships associated with a socket are also dropped when the socket is closed or the process holding the socket is killed. However, more than one socket may claim a membership in a particular group, and the host will remain a member of that group until the last claim is dropped.

The memberships associated with a socket do not necessarily determine which datagrams are received on that socket. Incoming multicast packets are accepted by the kernel IP layer if any socket has claimed a membership in the destination group of the datagram; however, delivery of a multicast datagram to a particular socket is based on the destination port (or protocol type, for raw sockets), just as with unicast datagrams. To receive multicast datagrams sent to a particular port, it is necessary to bind to that local port, leaving the local address unspecified (i.e., INADDR_ANY). To receive multicast datagrams sent to a particular group and port, bind to the local port, with the local address set to the multicast group address. Once bound to a multicast address, the socket cannot be used for sending data.

More than one process may bind to the same SOCK_DGRAM UDP port or the same multicast group and port if the bind call is preceded by: int on = 1; setsockopt(sock, SOL_SOCKET, SO_REUSEPORT, &on, sizeof(on)); All processes sharing the port must enable this option. Every incoming multicast or broadcast UDP datagram destined to the shared port is delivered to all sockets bound to the port. For backwards compatibility reasons, this does not apply to incoming unicast datagrams. Unicast datagrams are never delivered to more than one socket, regardless of how many sockets are bound to the datagram's destination port.

A final multicast-related extension is independent of IP: two new ioctls, SIOCADDMULTI and SIOCDELMULTI, are available to add or delete link-level (e.g., Ethernet) multicast addresses accepted by a particular interface. The address to be added or deleted is passed as a sockaddr structure of family AF_UNSPEC, within the standard ifreq structure.

These ioctls are for the use of protocols other than IP, and require superuser privileges. A link-level multicast address added via SIOCADDMULTI is not automatically deleted when the socket used to add it goes away; it must be explicitly deleted. It is inadvisable to delete a link-level address that may be in use by IP. Sample Multicast Program

The following program sends or receives multicast packets. If invoked with one argument, it sends a packet containing the current time to an arbitrarily-chosen multicast group and UDP port. If invoked with no arguments, it receives and prints these packets. Start it as a sender on just one host and as a receiver on all the other hosts. #include <sys/types.h> #include <sys/socket.h> #include <netinet/in.h> #include <arpa/inet.h> #include <time.h> #include <stdio.h> #define EXAMPLE_PORT 60123 #define EXAMPLE_GROUP "224.0.0.250" main(argc) int argc; { struct sockaddr_in addr; int addrlen, fd, cnt; struct ip_mreq mreq; char message[50]; fd = socket(AF_INET, SOCK_DGRAM, 0); if (fd < 0) { perror("socket"); exit(1); } bzero(&addr, sizeof(addr)); addr.sin_family = AF_INET; addr.sin_addr.s_addr = htonl(INADDR_ANY); addr.sin_port = htons(EXAMPLE_PORT); addrlen = sizeof(addr); if (argc > 1) { /* Send */ addr.sin_addr.s_addr = inet_addr(EXAMPLE_GROUP); while (1) { time_t t = time(0); sprintf(message, "time is %-24.24s", ctime(&t)); cnt = sendto(fd, message, sizeof(message), 0, (struct sockaddr *)&addr, addrlen); if (cnt < 0) { perror("sendto"); exit(1); } sleep(5); } } else { /* Receive */ if (bind(fd, (struct sockaddr *)&addr, sizeof(addr)) < 0) { perror("bind"); exit(1); } mreq.imr_multiaddr.s_addr = inet_addr(EXAMPLE_GROUP); mreq.imr_interface.s_addr = htonl(INADDR_ANY); if (setsockopt(fd, IPPROTO_IP, IP_ADD_MEMBERSHIP, &mreq, sizeof(mreq)) < 0) { perror("setsockopt mreq"); exit(1); } while (1) { cnt = recvfrom(fd, message, sizeof(message), 0, (struct sockaddr *)&addr, &addrlen); if (cnt <= 0) { if (cnt == 0) { break; } perror("recvfrom"); exit(1); } printf("%s: message = \e"%s\e"\en", inet_ntoa(addr.sin_addr), message); } } } ----------------------------------------------------------------------
NS Packet Sequences

The semantics of NS connections demand that the user both be able to look inside the network header associated with any incoming packet and be able to specify what should go in certain fields of an outgoing packet. Using different calls to setsockopt, it is possible to indicate whether prototype headers will be associated by the user with each outgoing packet (SO_HEADERS_ON_OUTPUT), to indicate whether the headers received by the system should be delivered to the user (SO_HEADERS_ON_INPUT), or to indicate default information that should be associated with all outgoing packets on a given socket (SO_DEFAULT_HEADERS).

The contents of a SPP header (minus the IDP header) are: struct sphdr { u_char sp_cc; /* connection control */ #define SP_SP 0x80 /* system packet */ #define SP_SA 0x40 /* send acknowledgement */ #define SP_OB 0x20 /* attention (out of band data) */ #define SP_EM 0x10 /* end of message */ u_char sp_dt; /* datastream type */ u_short sp_sid; /* source connection identifier */ u_short sp_did; /* destination connection identifier */ u_short sp_seq; /* sequence number */ u_short sp_ack; /* acknowledge number */ u_short sp_alo; /* allocation number */ }; Here, the items of interest are the datastream type and the connection control fields. The semantics of the datastream type are defined by the application(s) in question; the value of this field is, by default, zero, but it can be used to indicate things such as Xerox's Bulk Data Transfer Protocol (in which case it is set to one). The connection control field is a mask of the flags defined just below it. The user may set or clear the end-of-message bit to indicate that a given message is the last of a given substream type, or may set/clear the attention bit as an alternate way to indicate that a packet should be sent out-of-band. As an example, to associate prototype headers with outgoing SPP packets, consider: #include <sys/types.h> #include <sys/socket.h> #include <netns/ns.h> #include <netns/sp.h> ... struct sockaddr_ns sns, to; int s, on = 1; struct databuf { struct sphdr proto_spp; /* prototype header */ char buf[534]; /* max. possible data by Xerox std. */ } buf; ... s = socket(AF_NS, SOCK_SEQPACKET, 0); ... bind(s, (struct sockaddr *) &sns, sizeof (sns)); setsockopt(s, NSPROTO_SPP, SO_HEADERS_ON_OUTPUT, &on, sizeof(on)); ... buf.proto_spp.sp_dt = 1; /* bulk data */ buf.proto_spp.sp_cc = SP_EM; /* end-of-message */ strcpy(buf.buf, "hello world\en"); sendto(s, (char *) &buf, sizeof(struct sphdr) + strlen("hello world\en"), (struct sockaddr *) &to, sizeof(to)); ... Note that one must be careful when writing headers; if the prototype header is not written with the data with which it is to be associated, the kernel will treat the first few bytes of the data as the header, with unpredictable results. To turn off the above association, and to indicate that packet headers received by the system should be passed up to the user, one might use: #include <sys/types.h> #include <sys/socket.h> #include <netns/ns.h> #include <netns/sp.h> ... struct sockaddr sns; int s, on = 1, off = 0; ... s = socket(AF_NS, SOCK_SEQPACKET, 0); ... bind(s, (struct sockaddr *) &sns, sizeof (sns)); setsockopt(s, NSPROTO_SPP, SO_HEADERS_ON_OUTPUT, &off, sizeof(off)); setsockopt(s, NSPROTO_SPP, SO_HEADERS_ON_INPUT, &on, sizeof(on)); ...

Output is handled somewhat differently in the IDP world. The header of an IDP-level packet looks like: struct idp { u_short idp_sum; /* Checksum */ u_short idp_len; /* Length, in bytes, including header */ u_char idp_tc; /* Transport Control (i.e., hop count) */ u_char idp_pt; /* Packet Type (i.e., level 2 protocol) */ struct ns_addr idp_dna; /* Destination Network Address */ struct ns_addr idp_sna; /* Source Network Address */ }; The primary field of interest in an IDP header is the packet type field. The standard values for this field are (as defined in <netns/ns.h>): #define NSPROTO_RI 1 /* Routing Information */ #define NSPROTO_ECHO 2 /* Echo Protocol */ #define NSPROTO_ERROR 3 /* Error Protocol */ #define NSPROTO_PE 4 /* Packet Exchange */ #define NSPROTO_SPP 5 /* Sequenced Packet */ For SPP connections, the contents of this field are automatically set to NSPROTO_SPP; for IDP packets, this value defaults to zero, which means ``unknown''.

Setting the value of that field with SO_DEFAULT_HEADERS is easy: #include <sys/types.h> #include <sys/socket.h> #include <netns/ns.h> #include <netns/idp.h> ... struct sockaddr sns; struct idp proto_idp; /* prototype header */ int s, on = 1; ... s = socket(AF_NS, SOCK_DGRAM, 0); ... bind(s, (struct sockaddr *) &sns, sizeof (sns)); proto_idp.idp_pt = NSPROTO_PE; /* packet exchange */ setsockopt(s, NSPROTO_IDP, SO_DEFAULT_HEADERS, (char *) &proto_idp, sizeof(proto_idp)); ...

Using SO_HEADERS_ON_OUTPUT is somewhat more difficult. When SO_HEADERS_ON_OUTPUT is turned on for an IDP socket, the socket becomes (for all intents and purposes) a raw socket. In this case, all the fields of the prototype header (except the length and checksum fields, which are computed by the kernel) must be filled in correctly in order for the socket to send and receive data in a sensible manner. To be more specific, the source address must be set to that of the host sending the data; the destination address must be set to that of the host for whom the data is intended; the packet type must be set to whatever value is desired; and the hopcount must be set to some reasonable value (almost always zero). It should also be noted that simply sending data using write will not work unless a connect or sendto call is used, in spite of the fact that it is the destination address in the prototype header that is used, not the one given in either of those calls. For almost all IDP applications , using SO_DEFAULT_HEADERS is easier and more desirable than writing headers. Three-way Handshake

The semantics of SPP connections indicates that a three-way handshake, involving changes in the datastream type, should \(em but is not absolutely required to \(em take place before a SPP connection is closed. Almost all SPP connections are ``well-behaved'' in this manner; when communicating with any process, it is best to assume that the three-way handshake is required unless it is known for certain that it is not required. In a three-way close, the closing process indicates that it wishes to close the connection by sending a zero-length packet with end-of-message set and with datastream type 254. The other side of the connection indicates that it is OK to close by sending a zero-length packet with end-of-message set and datastream type 255. Finally, the closing process replies with a zero-length packet with substream type 255; at this point, the connection is considered closed. The following code fragments are simplified examples of how one might handle this three-way handshake at the user level; in the future, support for this type of close will probably be provided as part of the C library or as part of the kernel. The first code fragment below illustrates how a process might handle three-way handshake if it sees that the process it is communicating with wants to close the connection: #include <sys/types.h> #include <sys/socket.h> #include <netns/ns.h> #include <netns/sp.h> ... #ifndef SPPSST_END #define SPPSST_END 254 #define SPPSST_ENDREPLY 255 #endif struct sphdr proto_sp; int s; ... read(s, buf, BUFSIZE); if (((struct sphdr *)buf)->sp_dt == SPPSST_END) { /* * SPPSST_END indicates that the other side wants to * close. */ proto_sp.sp_dt = SPPSST_ENDREPLY; proto_sp.sp_cc = SP_EM; setsockopt(s, NSPROTO_SPP, SO_DEFAULT_HEADERS, (char *)&proto_sp, sizeof(proto_sp)); write(s, buf, 0); /* * Write a zero-length packet with datastream type = SPPSST_ENDREPLY * to indicate that the close is OK with us. The packet that we * don't see (because we don't look for it) is another packet * from the other side of the connection, with SPPSST_ENDREPLY * on it it, too. Once that packet is sent, the connection is * considered closed; note that we really ought to retransmit * the close for some time if we do not get a reply. */ close(s); } ... To indicate to another process that we would like to close the connection, the following code would suffice: #include <sys/types.h> #include <sys/socket.h> #include <netns/ns.h> #include <netns/sp.h> ... #ifndef SPPSST_END #define SPPSST_END 254 #define SPPSST_ENDREPLY 255 #endif struct sphdr proto_sp; int s; ... proto_sp.sp_dt = SPPSST_END; proto_sp.sp_cc = SP_EM; setsockopt(s, NSPROTO_SPP, SO_DEFAULT_HEADERS, (char *)&proto_sp, sizeof(proto_sp)); write(s, buf, 0); /* send the end request */ proto_sp.sp_dt = SPPSST_ENDREPLY; setsockopt(s, NSPROTO_SPP, SO_DEFAULT_HEADERS, (char *)&proto_sp, sizeof(proto_sp)); /* * We assume (perhaps unwisely) * that the other side will send the * ENDREPLY, so we'll just send our final ENDREPLY * as if we'd seen theirs already. */ write(s, buf, 0); close(s); ... Packet Exchange

The Xerox standard protocols include a protocol that is both reliable and datagram-oriented. This protocol is known as Packet Exchange (PEX or PE) and, like SPP, is layered on top of IDP. PEX is important for a number of things: Courier remote procedure calls may be expedited through the use of PEX, and many Xerox servers are located by doing a PEX ``BroadcastForServers'' operation. Although there is no implementation of PEX in the kernel, it may be simulated at the user level with some clever coding and the use of one peculiar getsockopt. A PEX packet looks like: /* * The packet-exchange header shown here is not defined * as part of any of the system include files. */ struct pex { struct idp p_idp; /* idp header */ u_short ph_id[2]; /* unique transaction ID for pex */ u_short ph_client; /* client type field for pex */ }; The ph_id field is used to hold a ``unique id'' that is used in duplicate suppression; the ph_client field indicates the PEX client type (similar to the packet type field in the IDP header). PEX reliability stems from the fact that it is an idempotent (``I send a packet to you, you send a packet to me'') protocol. Processes on each side of the connection may use the unique id to determine if they have seen a given packet before (the unique id field differs on each packet sent) so that duplicates may be detected, and to indicate which message a given packet is in response to. If a packet with a given unique id is sent and no response is received in a given amount of time, the packet is retransmitted until it is decided that no response will ever be received. To simulate PEX, one must be able to generate unique ids -- something that is hard to do at the user level with any real guarantee that the id is really unique. Therefore, a means (via getsockopt) has been provided for getting unique ids from the kernel. The following code fragment indicates how to get a unique id: long uniqueid; int s, idsize = sizeof(uniqueid); ... s = socket(AF_NS, SOCK_DGRAM, 0); ... /* get id from the kernel -- only on IDP sockets */ getsockopt(s, NSPROTO_PE, SO_SEQNO, (char *)&uniqueid, &idsize); ... The retransmission and duplicate suppression code required to simulate PEX fully is left as an exercise for the reader. Inetd

One of the daemons provided with 4.4BSD is inetd, the so called ``internet super-server.'' Having one daemon listen for requests for many daemons instead of having each daemon listen for its own requests reduces the number of idle daemons and simplies their implementation. Inetd handles two types of services: standard and TCPMUX. A standard service has a well-known port assigned to it and is listed in /etc/services (see \f2services\f1(5)); it may be a service that implements an official Internet standard or is a BSD-specific service. TCPMUX services are nonstandard and do not have a well-known port assigned to them. They are invoked from inetd when a program connects to the "tcpmux" well-known port and specifies the service name. This is useful for adding locally-developed servers.

Inetd is invoked at boot time, and determines from the file /etc/inetd.conf the servers for which it is to listen. Once this information has been read and a pristine environment created, inetd proceeds to create one socket for each service it is to listen for, binding the appropriate port number to each socket.

Inetd then performs a select on all these sockets for read availability, waiting for somebody wishing a connection to the service corresponding to that socket. Inetd then performs an accept on the socket in question, forks, dups the new socket to file descriptors 0 and 1 (stdin and stdout), closes other open file descriptors, and execs the appropriate server.

Servers making use of inetd are considerably simplified, as inetd takes care of the majority of the IPC work required in establishing a connection. The server invoked by inetd expects the socket connected to its client on file descriptors 0 and 1, and may immediately perform any operations such as read, write, send, or recv. Indeed, servers may use buffered I/O as provided by the ``stdio'' conventions, as long as they remember to use fflush when appropriate.

One call which may be of interest to individuals writing servers under inetd is the getpeername call, which returns the address of the peer (process) connected on the other end of the socket. For example, to log the Internet address in ``dot notation'' (e.g., ``128.32.0.4'') of a client connected to a server under inetd, the following code might be used: struct sockaddr_in name; int namelen = sizeof (name); ... if (getpeername(0, (struct sockaddr *)&name, &namelen) < 0) { syslog(LOG_ERR, "getpeername: %m"); exit(1); } else syslog(LOG_INFO, "Connection from %s", inet_ntoa(name.sin_addr)); ... While the getpeername call is especially useful when writing programs to run with inetd, it can be used under other circumstances. Be warned, however, that getpeername will fail on UNIX domain sockets.

Standard TCP services are assigned unique well-known port numbers in the range of 0 to 1023 by the Internet Assigned Numbers Authority (IANA@ISI.EDU). The limited number of ports in this range are assigned to official Internet protocols. The TCPMUX service allows you to add locally-developed protocols without needing an official TCP port assignment. The TCPMUX protocol described in RFC-1078 is simple: .QP ``A TCP client connects to a foreign host on TCP port 1. It sends the service name followed by a carriage-return line-feed <CRLF>. The service name is never case sensitive. The server replies with a single character indicating positive ("+") or negative ("-") acknowledgment, immediately followed by an optional message of explanation, terminated with a <CRLF>. If the reply was positive, the selected protocol begins; otherwise the connection is closed.''

In 4.4BSD, the TCPMUX service is built into inetd , that is, inetd listens on TCP port 1 for requests for TCPMUX services listed in \f2inetd.conf\f1. inetd (8) describes the format of TCPMUX entries for \f2inetd.conf\f1.

The following is an example TCPMUX server and its \f2inetd.conf\f1 entry. More sophisticated servers may want to do additional processing before returning the positive or negative acknowledgement. #include <sys/types.h> #include <stdio.h> main() { time_t t; printf("+Go\er\en"); fflush(stdout); time(&t); printf("%d = %s", t, ctime(&t)); fflush(stdout); } The \f2inetd.conf\f1 entry is: tcpmux/current_time stream tcp nowait nobody /d/curtime curtime Here's the portion of the client code that handles the TCPMUX handshake: char line[BUFSIZ]; FILE *fp; ... /* Use stdio for reading data from the server */ fp = fdopen(sock, "r"); if (fp == NULL) { fprintf(stderr, "Can't create file pointer\en"); exit(1); } /* Send service request */ sprintf(line, "%s\er\en", "current_time"); if (write(sock, line, strlen(line)) < 0) { perror("write"); exit(1); } /* Get ACK/NAK response from the server */ if (fgets(line, sizeof(line), fp) == NULL) { if (feof(fp)) { die(); } else { fprintf(stderr, "Error reading response\en"); exit(1); } } /* Delete <CR> */ if ((lp = index(line, '\r')) != NULL) { *lp = '\0'; } switch (line[0]) { case '+': printf("Got ACK: %s\en", &line[1]); break; case '-': printf("Got NAK: %s\en", &line[1]); exit(0); default: printf("Got unknown response: %s\en", line); exit(1); } /* Get rest of data from the server */ while ((fgets(line, sizeof(line), fp)) != NULL) { fputs(line, stdout); }