Copyright © 2015 Brian "Beej Jorgensen" Hall
Hey! Socket programming got you down? Is this stuff just a little
too difficult to figure out from the man pages? You want to
do cool Internet programming, but you don't have time to wade through a
gob of
Well, guess what! I've already done this nasty business, and I'm dying to share the information with everyone! You've come to the right place. This document should give the average competent C programmer the edge s/he needs to get a grip on this networking noise.
And check it out: I've finally caught up with the future (just in the nick of time, too!) and have updated the Guide for IPv6! Enjoy!
This document has been written as a tutorial, not a complete reference. It is probably at its best when read by individuals who are just starting out with socket programming and are looking for a foothold. It is certainly not the complete and total guide to sockets programming, by any means.
Hopefully, though, it'll be just enough for those man pages to start making sense... :-)
The code contained within this document was compiled on a Linux PC using Gnu's gcc compiler. It should, however, build on just about any platform that uses gcc. Naturally, this doesn't apply if you're programming for Windows—see the section on Windows programming, below.
This official location of this document is http://beej.us/guide/bgnet/. There you will also find example code and translations of the guide into various languages.
To buy nicely bound print copies (some call them "books"), visit http://beej.us/guide/url/bgbuy. I'll appreciate the purchase because it helps sustain my document-writing lifestyle!
When compiling for Solaris or SunOS, you need to specify some extra command-line switches
for linking in the proper libraries. In order to do this, simply add
"
$ cc -o server server.c -lnsl -lsocket -lresolv
If you still get errors, you could try further adding a "-lxnet" to the end of that command line. I don't know what that does, exactly, but some people seem to need it.
Another place that you might find problems is in the call to setsockopt(). The prototype differs from that on my Linux box, so instead of:
int yes=1;
enter this:
char yes='1';
As I don't have a Sun box, I haven't tested any of the above information—it's just what people have told me through email.
At this point in the guide, historically, I've done a bit of bagging on Windows, simply due to the fact that I don't like it very much. But I should really be fair and tell you that Windows has a huge install base and is obviously a perfectly fine operating system.
They say absence makes the heart grow fonder, and in this case, I believe it to be true. (Or maybe it's age.) But what I can say is that after a decade-plus of not using Microsoft OSes for my personal work, I'm much happier! As such, I can sit back and safely say, "Sure, feel free to use Windows!" ...Ok yes, it does make me grit my teeth to say that.
So I still encourage you to try Linux, BSD, or some flavor of Unix, instead.
But people like what they like, and you Windows folk will be pleased to know that this information is generally applicable to you guys, with a few minor changes, if any.
One cool thing you can do is install Cygwin, which is a collection of Unix tools for Windows. I've heard on the grapevine that doing so allows all these programs to compile unmodified.
But some of you might want to do things the Pure Windows Way. That's very gutsy of you, and this is what you have to do: run out and get Unix immediately! No, no—I'm kidding. I'm supposed to be Windows-friendly(er) these days...
This is what you'll have to do (unless you install Cygwin!): first, ignore pretty much all of the system header files I mention in here. All you need to include is:
#include <winsock.h>
Wait! You also have to make a call to WSAStartup() before doing anything else with the sockets library. The code to do that looks something like this:
#include <winsock.h> { WSADATA wsaData; // if this doesn't work //WSAData wsaData; // then try this instead // MAKEWORD(1,1) for Winsock 1.1, MAKEWORD(2,0) for Winsock 2.0: if (WSAStartup(MAKEWORD(1,1), &wsaData) != 0) { fprintf(stderr, "WSAStartup failed.\n"); exit(1); }
You also have to tell your compiler to link in the Winsock library, usually called wsock32.lib or winsock32.lib, or ws2_32.lib for Winsock 2.0. Under VC++, this can be done through the Project menu, under Settings.... Click the Link tab, and look for the box titled "Object/library modules". Add "wsock32.lib" (or whichever lib is your preference) to that list.
Or so I hear.
Finally, you need to call WSACleanup() when you're all through with the sockets library. See your online help for details.
Once you do that, the rest of the examples in this tutorial should generally apply, with a few exceptions. For one thing, you can't use close() to close a socket—you need to use closesocket(), instead. Also, select() only works with socket descriptors, not file descriptors (like 0 for stdin).
There is also a socket class that you can use,
To get more information about Winsock, read the Winsock FAQ and go from there.
Finally, I hear that Windows has no fork() system call which is, unfortunately, used in some of my examples. Maybe you have to link in a POSIX library or something to get it to work, or you can use CreateProcess() instead. fork() takes no arguments, and CreateProcess() takes about 48 billion arguments. If you're not up to that, the CreateThread() is a little easier to digest...unfortunately a discussion about multithreading is beyond the scope of this document. I can only talk about so much, you know!
I'm generally available to help out with email questions so feel free to write in, but I can't guarantee a response. I lead a pretty busy life and there are times when I just can't answer a question you have. When that's the case, I usually just delete the message. It's nothing personal; I just won't ever have the time to give the detailed answer you require.
As a rule, the more complex the question, the less likely I am to respond. If you can narrow down your question before mailing it and be sure to include any pertinent information (like platform, compiler, error messages you're getting, and anything else you think might help me troubleshoot), you're much more likely to get a response. For more pointers, read ESR's document, How To Ask Questions The Smart Way.
If you don't get a response, hack on it some more, try to find the answer, and if it's still elusive, then write me again with the information you've found and hopefully it will be enough for me to help out.
Now that I've badgered you about how to write and not write me, I'd just like to let you know that I fully appreciate all the praise the guide has received over the years. It's a real morale boost, and it gladdens me to hear that it is being used for good! :-) Thank you!
You are more than welcome to mirror this site, whether publicly or privately. If you publicly mirror the site and want me to link to it from the main page, drop me a line at beej@beej.us.
If you want to translate the guide into another language, write me at beej@beej.us and I'll link to your translation from the main page. Feel free to add your name and contact info to the translation.
Please note the license restrictions in the Copyright and Distribution section, below.
If you want me to host the translation, just ask. I'll also link to it if you want to host it; either way is fine.
Beej's Guide to Network Programming is Copyright © 2015 Brian "Beej Jorgensen" Hall.
With specific exceptions for source code and translations, below, this work is licensed under the Creative Commons Attribution- Noncommercial- No Derivative Works 3.0 License. To view a copy of this license, visit http://creativecommons.org/licenses/by-nc-nd/3.0/ or send a letter to Creative Commons, 171 Second Street, Suite 300, San Francisco, California, 94105, USA.
One specific exception to the "No Derivative Works" portion of the license is as follows: this guide may be freely translated into any language, provided the translation is accurate, and the guide is reprinted in its entirety. The same license restrictions apply to the translation as to the original guide. The translation may also include the name and contact information for the translator.
The C source code presented in this document is hereby granted to the public domain, and is completely free of any license restriction.
Educators are freely encouraged to recommend or supply copies of this guide to their students.
Contact beej@beej.us for more information.
You hear talk of "sockets" all the time, and perhaps you are wondering just what they are exactly. Well, they're this: a way to speak to other programs using standard Unix file descriptors.
What?
Ok—you may have heard some Unix hacker state, "Jeez, everything in Unix is a file!" What that person may have been talking about is the fact that when Unix programs do any sort of I/O, they do it by reading or writing to a file descriptor. A file descriptor is simply an integer associated with an open file. But (and here's the catch), that file can be a network connection, a FIFO, a pipe, a terminal, a real on-the-disk file, or just about anything else. Everything in Unix is a file! So when you want to communicate with another program over the Internet you're gonna do it through a file descriptor, you'd better believe it.
"Where do I get this file descriptor for network communication, Mr. Smarty-Pants?" is probably the last question on your mind right now, but I'm going to answer it anyway: You make a call to the socket() system routine. It returns the socket descriptor, and you communicate through it using the specialized send() and recv() (man send, man recv) socket calls.
"But, hey!" you might be exclaiming right about now. "If it's a file descriptor, why in the name of Neptune can't I just use the normal read() and write() calls to communicate through the socket?" The short answer is, "You can!" The longer answer is, "You can, but send() and recv() offer much greater control over your data transmission."
What next? How about this: there are all kinds of sockets. There are DARPA Internet addresses (Internet Sockets), path names on a local node (Unix Sockets), CCITT X.25 addresses (X.25 Sockets that you can safely ignore), and probably many others depending on which Unix flavor you run. This document deals only with the first: Internet Sockets.
What's this? There are two types of Internet sockets? Yes. Well, no. I'm lying. There are more, but I didn't want to scare you. I'm only going to talk about two types here. Except for this sentence, where I'm going to tell you that "Raw Sockets" are also very powerful and you should look them up.
All right, already. What are the two types? One is "Stream Sockets"; the other is "Datagram Sockets", which may hereafter be referred to as "SOCK_STREAM" and "SOCK_DGRAM", respectively. Datagram sockets are sometimes called "connectionless sockets". (Though they can be connect()'d if you really want. See connect(), below.)
Stream sockets are reliable two-way connected communication streams. If you output two items into the socket in the order "1, 2", they will arrive in the order "1, 2" at the opposite end. They will also be error-free. I'm so certain, in fact, they will be error-free, that I'm just going to put my fingers in my ears and chant la la la la if anyone tries to claim otherwise.
What uses stream sockets? Well, you may have heard of the telnet application, yes? It uses stream sockets. All the characters you type need to arrive in the same order you type them, right? Also, web browsers use the HTTP protocol which uses stream sockets to get pages. Indeed, if you telnet to a web site on port 80, and type "GET / HTTP/1.0" and hit RETURN twice, it'll dump the HTML back at you!
How do stream sockets achieve this high level of data transmission quality? They use a protocol called "The Transmission Control Protocol", otherwise known as "TCP" (see RFC 793 for extremely detailed info on TCP.) TCP makes sure your data arrives sequentially and error-free. You may have heard "TCP" before as the better half of "TCP/IP" where "IP" stands for "Internet Protocol" (see RFC 791.) IP deals primarily with Internet routing and is not generally responsible for data integrity.
Cool. What about Datagram sockets? Why are they called connectionless? What is the deal, here, anyway? Why are they unreliable? Well, here are some facts: if you send a datagram, it may arrive. It may arrive out of order. If it arrives, the data within the packet will be error-free.
Datagram sockets also use IP for routing, but they don't use TCP; they use the "User Datagram Protocol", or "UDP" (see RFC 768.)
Why are they connectionless? Well, basically, it's because you don't have to maintain an open connection as you do with stream sockets. You just build a packet, slap an IP header on it with destination information, and send it out. No connection needed. They are generally used either when a TCP stack is unavailable or when a few dropped packets here and there don't mean the end of the Universe. Sample applications: tftp (trivial file transfer protocol, a little brother to FTP), dhcpcd (a DHCP client), multiplayer games, streaming audio, video conferencing, etc.
"Wait a minute! tftp and dhcpcd are used to transfer binary applications from one host to another! Data can't be lost if you expect the application to work when it arrives! What kind of dark magic is this?"
Well, my human friend, tftp and similar programs have their own protocol on top of UDP. For example, the tftp protocol says that for each packet that gets sent, the recipient has to send back a packet that says, "I got it!" (an "ACK" packet.) If the sender of the original packet gets no reply in, say, five seconds, he'll re-transmit the packet until he finally gets an ACK. This acknowledgment procedure is very important when implementing reliable SOCK_DGRAM applications.
For unreliable applications like games, audio, or video, you just ignore the dropped packets, or perhaps try to cleverly compensate for them. (Quake players will know the manifestation this effect by the technical term: accursed lag. The word "accursed", in this case, represents any extremely profane utterance.)
Why would you use an unreliable underlying protocol? Two reasons: speed and speed. It's way faster to fire-and-forget than it is to keep track of what has arrived safely and make sure it's in order and all that. If you're sending chat messages, TCP is great; if you're sending 40 positional updates per second of the players in the world, maybe it doesn't matter so much if one or two get dropped, and UDP is a good choice.
Since I just mentioned layering of protocols, it's time to talk about how networks really work, and to show some examples of how SOCK_DGRAM packets are built. Practically, you can probably skip this section. It's good background, however.
Data Encapsulation.
Hey, kids, it's time to learn about Data Encapsulation! This is very very important. It's so important that you might just learn about it if you take the networks course here at Chico State ;-). Basically, it says this: a packet is born, the packet is wrapped ("encapsulated") in a header (and rarely a footer) by the first protocol (say, the TFTP protocol), then the whole thing (TFTP header included) is encapsulated again by the next protocol (say, UDP), then again by the next (IP), then again by the final protocol on the hardware (physical) layer (say, Ethernet).
When another computer receives the packet, the hardware strips the Ethernet header, the kernel strips the IP and UDP headers, the TFTP program strips the TFTP header, and it finally has the data.
Now I can finally talk about the infamous Layered Network Model (aka "ISO/OSI"). This Network Model describes a system of network functionality that has many advantages over other models. For instance, you can write sockets programs that are exactly the same without caring how the data is physically transmitted (serial, thin Ethernet, AUI, whatever) because programs on lower levels deal with it for you. The actual network hardware and topology is transparent to the socket programmer.
Without any further ado, I'll present the layers of the full-blown model. Remember this for network class exams:
The Physical Layer is the hardware (serial, Ethernet, etc.). The Application Layer is just about as far from the physical layer as you can imagine—it's the place where users interact with the network.
Now, this model is so general you could probably use it as an automobile repair guide if you really wanted to. A layered model more consistent with Unix might be:
At this point in time, you can probably see how these layers correspond to the encapsulation of the original data.
See how much work there is in building a simple packet? Jeez! And you have to type in the packet headers yourself using "cat"! Just kidding. All you have to do for stream sockets is send() the data out. All you have to do for datagram sockets is encapsulate the packet in the method of your choosing and sendto() it out. The kernel builds the Transport Layer and Internet Layer on for you and the hardware does the Network Access Layer. Ah, modern technology.
So ends our brief foray into network theory. Oh yes, I forgot to tell you everything I wanted to say about routing: nothing! That's right, I'm not going to talk about it at all. The router strips the packet to the IP header, consults its routing table, blah blah blah. Check out the IP RFC if you really really care. If you never learn about it, well, you'll live.
Here's the part of the game where we get to talk code for a change.
But first, let's discuss more non-code! Yay! First I want to talk about IP addresses and ports for just a tad so we have that sorted out. Then we'll talk about how the sockets API stores and manipulates IP addresses and other data.
In the good old days back when Ben Kenobi was still called Obi Wan Kenobi, there was a wonderful network routing system called The Internet Protocol Version 4, also called IPv4. It had addresses made up of four bytes (A.K.A. four "octets"), and was commonly written in "dots and numbers" form, like so: 192.0.2.111.
You've probably seen it around.
In fact, as of this writing, virtually every site on the Internet uses IPv4.
Everyone, including Obi Wan, was happy. Things were great, until some naysayer by the name of Vint Cerf warned everyone that we were about to run out of IPv4 addresses!
(Besides warning everyone of the Coming IPv4 Apocalypse Of Doom And Gloom, Vint Cerf is also well-known for being The Father Of The Internet. So I really am in no position to second-guess his judgment.)
Run out of addresses? How could this be? I mean, there are like billions of IP addresses in a 32-bit IPv4 address. Do we really have billions of computers out there?
Yes.
Also, in the beginning, when there were only a few computers and everyone thought a billion was an impossibly large number, some big organizations were generously allocated millions of IP addresses for their own use. (Such as Xerox, MIT, Ford, HP, IBM, GE, AT&T, and some little company called Apple, to name a few.)
In fact, if it weren't for several stopgap measures, we would have run out a long time ago.
But now we're living in an era where we're talking about every human having an IP address, every computer, every calculator, every phone, every parking meter, and (why not) every puppy dog, as well.
And so, IPv6 was born. Since Vint Cerf is probably immortal (even if his physical form should pass on, heaven forbid, he is probably already existing as some kind of hyper-intelligent ELIZA program out in the depths of the Internet2), no one wants to have to hear him say again "I told you so" if we don't have enough addresses in the next version of the Internet Protocol.
What does this suggest to you?
That we need a lot more addresses. That we need not just twice as many addresses, not a billion times as many, not a thousand trillion times as many, but 79 MILLION BILLION TRILLION times as many possible addresses! That'll show 'em!
You're saying, "Beej, is that true? I have every reason to disbelieve large numbers." Well, the difference between 32 bits and 128 bits might not sound like a lot; it's only 96 more bits, right? But remember, we're talking powers here: 32 bits represents some 4 billion numbers (232), while 128 bits represents about 340 trillion trillion trillion numbers (for real, 2128). That's like a million IPv4 Internets for every single star in the Universe.
Forget this dots-and-numbers look of IPv4, too; now we've got a hexadecimal representation, with each two-byte chunk separated by a colon, like this: 2001:0db8:c9d2:aee5:73e3:934a:a5ae:9551.
That's not all! Lots of times, you'll have an IP address with lots of zeros in it, and you can compress them between two colons. And you can leave off leading zeros for each byte pair. For instance, each of these pairs of addresses are equivalent:
2001:0db8:c9d2:0012:0000:0000:0000:0051 2001:db8:c9d2:12::51 2001:0db8:ab00:0000:0000:0000:0000:0000 2001:db8:ab00:: 0000:0000:0000:0000:0000:0000:0000:0001 ::1
The address ::1 is the loopback address. It always means "this machine I'm running on now". In IPv4, the loopback address is 127.0.0.1.
Finally, there's an IPv4-compatibility mode for IPv6 addresses that you might come across. If you want, for example, to represent the IPv4 address 192.0.2.33 as an IPv6 address, you use the following notation: "::ffff:192.0.2.33".
We're talking serious fun.
In fact, it's such serious fun, that the Creators of IPv6 have quite cavalierly lopped off trillions and trillions of addresses for reserved use, but we have so many, frankly, who's even counting anymore? There are plenty left over for every man, woman, child, puppy, and parking meter on every planet in the galaxy. And believe me, every planet in the galaxy has parking meters. You know it's true.
For organizational reasons, it's sometimes convenient to declare that "this first part of this IP address up through this bit is the network portion of the IP address, and the remainder is the host portion.
For instance, with IPv4, you might have 192.0.2.12, and we could say that the first three bytes are the network and the last byte was the host. Or, put another way, we're talking about host 12 on network 192.0.2.0 (see how we zero out the byte that was the host.)
And now for more outdated information! Ready? In the Ancient Times, there were "classes" of subnets, where the first one, two, or three bytes of the address was the network part. If you were lucky enough to have one byte for the network and three for the host, you could have 24 bits-worth of hosts on your network (16 million or so). That was a "Class A" network. On the opposite end was a "Class C", with three bytes of network, and one byte of host (256 hosts, minus a couple that were reserved.)
So as you can see, there were just a few Class As, a huge pile of Class Cs, and some Class Bs in the middle.
The network portion of the IP address is described by something called the netmask, which you bitwise-AND with the IP address to get the network number out of it. The netmask usually looks something like 255.255.255.0. (E.g. with that netmask, if your IP is 192.0.2.12, then your network is 192.0.2.12 AND 255.255.255.0 which gives 192.0.2.0.)
Unfortunately, it turned out that this wasn't fine-grained enough for the eventual needs of the Internet; we were running out of Class C networks quite quickly, and we were most definitely out of Class As, so don't even bother to ask. To remedy this, The Powers That Be allowed for the netmask to be an arbitrary number of bits, not just 8, 16, or 24. So you might have a netmask of, say 255.255.255.252, which is 30 bits of network, and 2 bits of host allowing for four hosts on the network. (Note that the netmask is ALWAYS a bunch of 1-bits followed by a bunch of 0-bits.)
But it's a bit unwieldy to use a big string of numbers like 255.192.0.0 as a netmask. First of all, people don't have an intuitive idea of how many bits that is, and secondly, it's really not compact. So the New Style came along, and it's much nicer. You just put a slash after the IP address, and then follow that by the number of network bits in decimal. Like this: 192.0.2.12/30.
Or, for IPv6, something like this: 2001:db8::/32 or 2001:db8:5413:4028::9db9/64.
If you'll kindly remember, I presented you earlier with the Layered Network Model which had the Internet Layer (IP) split off from the Host-to-Host Transport Layer (TCP and UDP). Get up to speed on that before the next paragraph.
Turns out that besides an IP address (used by the IP layer), there is another address that is used by TCP (stream sockets) and, coincidentally, by UDP (datagram sockets). It is the port number. It's a 16-bit number that's like the local address for the connection.
Think of the IP address as the street address of a hotel, and the port number as the room number. That's a decent analogy; maybe later I'll come up with one involving the automobile industry.
Say you want to have a computer that handles incoming mail AND web services—how do you differentiate between the two on a computer with a single IP address?
Well, different services on the Internet have different well-known port numbers. You can see them all in the Big IANA Port List or, if you're on a Unix box, in your /etc/services file. HTTP (the web) is port 80, telnet is port 23, SMTP is port 25, the game DOOM used port 666, etc. and so on. Ports under 1024 are often considered special, and usually require special OS privileges to use.
And that's about it!
By Order of the Realm! There shall be two byte orderings, hereafter to be known as Lame and Magnificent!
I joke, but one really is better than the other. :-)
There really is no easy way to say this, so I'll just blurt it out: your computer might have been storing bytes in reverse order behind your back. I know! No one wanted to have to tell you.
The thing is, everyone in the Internet world has generally agreed that if you want to represent the two-byte hex number, say b34f, you'll store it in two sequential bytes b3 followed by 4f. Makes sense, and, as Wilford Brimley would tell you, it's the Right Thing To Do. This number, stored with the big end first, is called Big-Endian.
Unfortunately, a few computers scattered here and there throughout the world, namely anything with an Intel or Intel-compatible processor, store the bytes reversed, so b34f would be stored in memory as the sequential bytes 4f followed by b3. This storage method is called Little-Endian.
But wait, I'm not done with terminology yet! The more-sane Big-Endian is also called Network Byte Order because that's the order us network types like.
Your computer stores numbers in Host Byte Order. If it's an Intel 80x86, Host Byte Order is Little-Endian. If it's a Motorola 68k, Host Byte Order is Big-Endian. If it's a PowerPC, Host Byte Order is... well, it depends!
A lot of times when you're building packets or filling out data structures you'll need to make sure your two- and four-byte numbers are in Network Byte Order. But how can you do this if you don't know the native Host Byte Order?
Good news! You just get to assume the Host Byte Order isn't right, and you always run the value through a function to set it to Network Byte Order. The function will do the magic conversion if it has to, and this way your code is portable to machines of differing endianness.
All righty. There are two types of numbers that you can convert:
It's almost too easy...
You can use every combination of "n", "h", "s", and "l" you want, not counting the really stupid ones. For example, there is NOT a stolh() ("Short to Long Host") function—not at this party, anyway. But there are:
host to network short |
|
host to network long |
|
network to host short |
|
network to host long |
Basically, you'll want to convert the numbers to Network Byte Order before they go out on the wire, and convert them to Host Byte Order as they come in off the wire.
I don't know of a 64-bit variant, sorry. And if you want to do floating point, check out the section on Serialization, far below.
Assume the numbers in this document are in Host Byte Order unless I say otherwise.
Well, we're finally here. It's time to talk about programming. In this section, I'll cover various data types used by the sockets interface, since some of them are a real bear to figure out.
First the easy one: a socket descriptor. A socket descriptor is the following type:
int
Just a regular
Things get weird from here, so just read through and bear with me.
My First StructTM—
struct addrinfo { int ai_flags; // AI_PASSIVE, AI_CANONNAME, etc. int ai_family; // AF_INET, AF_INET6, AF_UNSPEC int ai_socktype; // SOCK_STREAM, SOCK_DGRAM int ai_protocol; // use 0 for "any" size_t ai_addrlen; // size of ai_addr in bytes struct sockaddr *ai_addr; // struct sockaddr_in or _in6 char *ai_canonname; // full canonical hostname struct addrinfo *ai_next; // linked list, next node };
You'll load this struct up a bit, and then call getaddrinfo(). It'll return a pointer to a new linked list of these structures filled out with all the goodies you need.
You can force it to use IPv4 or IPv6 in the ai_family field, or leave it as AF_UNSPEC to use whatever. This is cool because your code can be IP version-agnostic.
Note that this is a linked list: ai_next points at the next element—there could be several results for you to choose from. I'd use the first result that worked, but you might have different business needs; I don't know everything, man!
You'll see that the ai_addr field in the
You might not usually need to write to these structures; oftentimes,
a call to getaddrinfo() to fill out your
(Also, all the code written before
Some
Anyway, the
struct sockaddr { unsigned short sa_family; // address family, AF_xxx char sa_data[14]; // 14 bytes of protocol address };
sa_family can be a variety of things, but it'll be AF_INET (IPv4) or AF_INET6 (IPv6) for everything we do in this document. sa_data contains a destination address and port number for the socket. This is rather unwieldy since you don't want to tediously pack the address in the sa_data by hand.
To deal with
And this is the important bit: a pointer to a
// (IPv4 only--see struct sockaddr_in6 for IPv6) struct sockaddr_in { short int sin_family; // Address family, AF_INET unsigned short int sin_port; // Port number struct in_addr sin_addr; // Internet address unsigned char sin_zero[8]; // Same size as struct sockaddr };
This structure makes it easy to reference elements of the socket
address. Note that sin_zero (which is included to pad
the structure to the length of a
Let's dig deeper! You see the sin_addr field is a
// (IPv4 only--see struct in6_addr for IPv6) // Internet address (a structure for historical reasons) struct in_addr { uint32_t s_addr; // that's a 32-bit int (4 bytes) };
Whoa! Well, it used to be a union, but now those days
seem to be gone. Good riddance. So if you have declared
ina to be of type
What about IPv6? Similar
// (IPv6 only--see struct sockaddr_in and struct in_addr for IPv4) struct sockaddr_in6 { u_int16_t sin6_family; // address family, AF_INET6 u_int16_t sin6_port; // port number, Network Byte Order u_int32_t sin6_flowinfo; // IPv6 flow information struct in6_addr sin6_addr; // IPv6 address u_int32_t sin6_scope_id; // Scope ID }; struct in6_addr { unsigned char s6_addr[16]; // IPv6 address };
Note that IPv6 has an IPv6 address and a port number, just like IPv4 has an IPv4 address and a port number.
Also note that I'm not going to talk about the IPv6 flow information or Scope ID fields for the moment... this is just a starter guide. :-)
Last but not least, here is another simple structure,
struct sockaddr_storage { sa_family_t ss_family; // address family // all this is padding, implementation specific, ignore it: char __ss_pad1[_SS_PAD1SIZE]; int64_t __ss_align; char __ss_pad2[_SS_PAD2SIZE]; };
What's important is that you can see the address family in the
ss_family field—check this to see if it's
AF_INET or AF_INET6 (for IPv4 or
IPv6). Then you can cast it to a
Fortunately for you, there are a bunch of functions that allow you to
manipulate IP addresses. No need to figure them out by
hand and stuff them in a
First, let's say you have a
struct sockaddr_in sa; // IPv4 struct sockaddr_in6 sa6; // IPv6 inet_pton(AF_INET, "10.12.110.57", &(sa.sin_addr)); // IPv4 inet_pton(AF_INET6, "2001:db8:63b3:1::3490", &(sa6.sin6_addr)); // IPv6
(Quick note: the old way of doing things used a function called inet_addr() or another function called inet_aton(); these are now obsolete and don't work with IPv6.)
Now, the above code snippet isn't very robust because there is no error checking. See, inet_pton() returns -1 on error, or 0 if the address is messed up. So check to make sure the result is greater than 0 before using!
All right, now you can convert string IP addresses to their binary
representations. What about the other way around? What if you have a
// IPv4: char ip4[INET_ADDRSTRLEN]; // space to hold the IPv4 string struct sockaddr_in sa; // pretend this is loaded with something inet_ntop(AF_INET, &(sa.sin_addr), ip4, INET_ADDRSTRLEN); printf("The IPv4 address is: %s\n", ip4); // IPv6: char ip6[INET6_ADDRSTRLEN]; // space to hold the IPv6 string struct sockaddr_in6 sa6; // pretend this is loaded with something inet_ntop(AF_INET6, &(sa6.sin6_addr), ip6, INET6_ADDRSTRLEN); printf("The address is: %s\n", ip6);
When you call it, you'll pass the address type (IPv4 or IPv6), the address, a pointer to a string to hold the result, and the maximum length of that string. (Two macros conveniently hold the size of the string you'll need to hold the largest IPv4 or IPv6 address: INET_ADDRSTRLEN and INET6_ADDRSTRLEN.)
(Another quick note to mention once again the old way of doing things: the historical function to do this conversion was called inet_ntoa(). It's also obsolete and won't work with IPv6.)
Lastly, these functions only work with numeric IP addresses—they won't do any nameserver DNS lookup on a hostname, like "www.example.com". You will use getaddrinfo() to do that, as you'll see later on.
Lots of places have a firewall that hides the network from the rest of the world for their own protection. And often times, the firewall translates "internal" IP addresses to "external" (that everyone else in the world knows) IP addresses using a process called Network Address Translation, or NAT.
Are you getting nervous yet? "Where's he going with all this weird stuff?"
Well, relax and buy yourself a non-alcoholic (or alcoholic) drink, because as a beginner, you don't even have to worry about NAT, since it's done for you transparently. But I wanted to talk about the network behind the firewall in case you started getting confused by the network numbers you were seeing.
For instance, I have a firewall at home. I have two static IPv4 addresses allocated to me by the DSL company, and yet I have seven computers on the network. How is this possible? Two computers can't share the same IP address, or else the data wouldn't know which one to go to!
The answer is: they don't share the same IP addresses. They are on a private network with 24 million IP addresses allocated to it. They are all just for me. Well, all for me as far as anyone else is concerned. Here's what's happening:
If I log into a remote computer, it tells me I'm logged in from 192.0.2.33 which is the public IP address my ISP has provided to me. But if I ask my local computer what its IP address is, it says 10.0.0.5. Who is translating the IP address from one to the other? That's right, the firewall! It's doing NAT!
10.x.x.x is one of a few reserved networks that are only to be used either on fully disconnected networks, or on networks that are behind firewalls. The details of which private network numbers are available for you to use are outlined in RFC 1918, but some common ones you'll see are 10.x.x.x and 192.168.x.x, where x is 0-255, generally. Less common is 172.y.x.x, where y goes between 16 and 31.
Networks behind a NATing firewall don't need to be on one of these reserved networks, but they commonly are.
(Fun fact! My external IP address isn't really 192.0.2.33. The 192.0.2.x network is reserved for make-believe "real" IP addresses to be used in documentation, just like this guide! Wowzers!)
IPv6 has private networks, too, in a sense. They'll start with fdxx: (or maybe in the future fcXX:), as per RFC 4193. NAT and IPv6 don't generally mix, however (unless you're doing the IPv6 to IPv4 gateway thing which is beyond the scope of this document)—in theory you'll have so many addresses at your disposal that you won't need to use NAT any longer. But if you want to allocate addresses for yourself on a network that won't route outside, this is how to do it.
But I just want to know what to change in my code to get it going with IPv6! Tell me now!
Ok! Ok!
Almost everything in here is something I've gone over, above, but it's the short version for the impatient. (Of course, there is more than this, but this is what applies to the guide.)
Change INADDR_ANY assignments to in6addr_any assignments, which are slightly different:
struct sockaddr_in sa; struct sockaddr_in6 sa6; sa.sin_addr.s_addr = INADDR_ANY; // use my IPv4 address sa6.sin6_addr = in6addr_any; // use my IPv6 address
Also, the value IN6ADDR_ANY_INIT can be used as an
initializer when the
struct in6_addr ia6 = IN6ADDR_ANY_INIT;
Et voila!
This is the section where we get into the system calls (and other library calls) that allow you to access the network functionality of a Unix box, or any box that supports the sockets API for that matter (BSD, Windows, Linux, Mac, what-have-you.) When you call one of these functions, the kernel takes over and does all the work for you automagically.
The place most people get stuck around here is what order to call these things in. In that, the man pages are no use, as you've probably discovered. Well, to help with that dreadful situation, I've tried to lay out the system calls in the following sections in exactly (approximately) the same order that you'll need to call them in your programs.
That, coupled with a few pieces of sample code here and there, some milk and cookies (which I fear you will have to supply yourself), and some raw guts and courage, and you'll be beaming data around the Internet like the Son of Jon Postel!
(Please note that for brevity, many code snippets below do not include necessary error checking. And they very commonly assume that the result from calls to getaddrinfo() succeed and return a valid entry in the linked list. Both of these situations are properly addressed in the stand-alone programs, though, so use those as a model.)
This is a real workhorse of a function with
a lot of options, but usage is actually pretty simple. It helps set up
the
A tiny bit of history: it used to be that you would use a function
called gethostbyname() to do DNS lookups. Then you'd
load that information by hand into a
This is no longer necessary, thankfully. (Nor is it desirable, if
you want to write code that works for both IPv4 and IPv6!) In these
modern times, you now have the function getaddrinfo() that
does all kinds of good stuff for you, including DNS and service name
lookups, and fills out the
Let's take a look!
#include <sys/types.h> #include <sys/socket.h> #include <netdb.h> int getaddrinfo(const char *node, // e.g. "www.example.com" or IP const char *service, // e.g. "http" or port number const struct addrinfo *hints, struct addrinfo **res);
You give this function three input parameters, and it gives you a pointer to a linked-list, res, of results.
The node parameter is the host name to connect to, or an IP address.
Next is the parameter service, which can be a port number, like "80", or the name of a particular service (found in The IANA Port List or the /etc/services file on your Unix machine) like "http" or "ftp" or "telnet" or "smtp" or whatever.
Finally, the hints parameter points to a
Here's a sample call if you're a server who wants to listen on your host's IP address, port 3490. Note that this doesn't actually do any listening or network setup; it merely sets up structures we'll use later:
int status; struct addrinfo hints; struct addrinfo *servinfo; // will point to the results memset(&hints, 0, sizeof hints); // make sure the struct is empty hints.ai_family = AF_UNSPEC; // don't care IPv4 or IPv6 hints.ai_socktype = SOCK_STREAM; // TCP stream sockets hints.ai_flags = AI_PASSIVE; // fill in my IP for me if ((status = getaddrinfo(NULL, "3490", &hints, &servinfo)) != 0) { fprintf(stderr, "getaddrinfo error: %s\n", gai_strerror(status)); exit(1); } // servinfo now points to a linked list of 1 or more struct addrinfos // ... do everything until you don't need servinfo anymore .... freeaddrinfo(servinfo); // free the linked-list
Notice that I set the ai_family to AF_UNSPEC, thereby saying that I don't care if we use IPv4 or IPv6. You can set it to AF_INET or AF_INET6 if you want one or the other specifically.
Also, you'll see the AI_PASSIVE flag in there; this tells getaddrinfo() to assign the address of my local host to the socket structures. This is nice because then you don't have to hardcode it. (Or you can put a specific address in as the first parameter to getaddrinfo() where I currently have NULL, up there.)
Then we make the call. If there's an error
(getaddrinfo() returns non-zero), we can print it out using
the function gai_strerror(), as you see. If everything
works properly, though, servinfo will point to a linked list
of
Finally, when we're eventually all done with the linked list that getaddrinfo() so graciously allocated for us, we can (and should) free it all up with a call to freeaddrinfo().
Here's a sample call if you're a client who wants to connect to a particular server, say "www.example.net" port 3490. Again, this doesn't actually connect, but it sets up the structures we'll use later:
int status; struct addrinfo hints; struct addrinfo *servinfo; // will point to the results memset(&hints, 0, sizeof hints); // make sure the struct is empty hints.ai_family = AF_UNSPEC; // don't care IPv4 or IPv6 hints.ai_socktype = SOCK_STREAM; // TCP stream sockets // get ready to connect status = getaddrinfo("www.example.net", "3490", &hints, &servinfo); // servinfo now points to a linked list of 1 or more struct addrinfos // etc.
I keep saying that servinfo is a linked list with all kinds of address information. Let's write a quick demo program to show off this information. This short program will print the IP addresses for whatever host you specify on the command line:
/* ** showip.c -- show IP addresses for a host given on the command line */ #include <stdio.h> #include <string.h> #include <sys/types.h> #include <sys/socket.h> #include <netdb.h> #include <arpa/inet.h> #include <netinet/in.h> int main(int argc, char *argv[]) { struct addrinfo hints, *res, *p; int status; char ipstr[INET6_ADDRSTRLEN]; if (argc != 2) { fprintf(stderr,"usage: showip hostname\n"); return 1; } memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; // AF_INET or AF_INET6 to force version hints.ai_socktype = SOCK_STREAM; if ((status = getaddrinfo(argv[1], NULL, &hints, &res)) != 0) { fprintf(stderr, "getaddrinfo: %s\n", gai_strerror(status)); return 2; } printf("IP addresses for %s:\n\n", argv[1]); for(p = res;p != NULL; p = p->ai_next) { void *addr; char *ipver; // get the pointer to the address itself, // different fields in IPv4 and IPv6: if (p->ai_family == AF_INET) { // IPv4 struct sockaddr_in *ipv4 = (struct sockaddr_in *)p->ai_addr; addr = &(ipv4->sin_addr); ipver = "IPv4"; } else { // IPv6 struct sockaddr_in6 *ipv6 = (struct sockaddr_in6 *)p->ai_addr; addr = &(ipv6->sin6_addr); ipver = "IPv6"; } // convert the IP to a string and print it: inet_ntop(p->ai_family, addr, ipstr, sizeof ipstr); printf(" %s: %s\n", ipver, ipstr); } freeaddrinfo(res); // free the linked list return 0; }
As you see, the code calls getaddrinfo() on whatever you pass on the command line, that fills out the linked list pointed to by res, and then we can iterate over the list and print stuff out or do whatever.
(There's a little bit of ugliness there where we have to dig into the
different types of
Sample run! Everyone loves screenshots:
$ showip www.example.net IP addresses for www.example.net: IPv4: 192.0.2.88 $ showip ipv6.example.com IP addresses for ipv6.example.com: IPv4: 192.0.2.101 IPv6: 2001:db8:8c00:22::171
Now that we have that under control, we'll use the results we get from getaddrinfo() to pass to other socket functions and, at long last, get our network connection established! Keep reading!
I guess I can put it off no longer—I have to talk about the socket() system call. Here's the breakdown:
#include <sys/types.h> #include <sys/socket.h> int socket(int domain, int type, int protocol);
But what are these arguments? They allow you to say what kind of socket you want (IPv4 or IPv6, stream or datagram, and TCP or UDP).
It used to be people would hardcode these values, and you can absolutely still do that. (domain is PF_INET or PF_INET6, type is SOCK_STREAM or SOCK_DGRAM, and protocol can be set to 0 to choose the proper protocol for the given type. Or you can call getprotobyname() to look up the protocol you want, "tcp" or "udp".)
(This PF_INET thing is a close relative of the AF_INET that you can use when initializing
the sin_family field in your
Anyway, enough of that. What you really want to do is use the values from the results of the call to getaddrinfo(), and feed them into socket() directly like this:
int s; struct addrinfo hints, *res; // do the lookup // [pretend we already filled out the "hints" struct] getaddrinfo("www.example.com", "http", &hints, &res); // [again, you should do error-checking on getaddrinfo(), and walk // the "res" linked list looking for valid entries instead of just // assuming the first one is good (like many of these examples do.) // See the section on client/server for real examples.] s = socket(res->ai_family, res->ai_socktype, res->ai_protocol);
socket() simply returns to you a socket descriptor that you can use in later system calls, or -1 on error. The global variable errno is set to the error's value (see the errno man page for more details, and a quick note on using errno in multithreaded programs.)
Fine, fine, fine, but what good is this socket? The answer is that it's really no good by itself, and you need to read on and make more system calls for it to make any sense.
Once you have a socket, you might have to associate that socket with a port on your local machine. (This is commonly done if you're going to listen() for incoming connections on a specific port—multiplayer network games do this when they tell you to "connect to 192.168.5.10 port 3490".) The port number is used by the kernel to match an incoming packet to a certain process's socket descriptor. If you're going to only be doing a connect() (because you're the client, not the server), this is probably be unnecessary. Read it anyway, just for kicks.
Here is the synopsis for the bind() system call:
#include <sys/types.h> #include <sys/socket.h> int bind(int sockfd, struct sockaddr *my_addr, int addrlen);
sockfd is the socket file descriptor returned by
socket(). my_addr is a pointer to a
Whew. That's a bit to absorb in one chunk. Let's have an example that binds the socket to the host the program is running on, port 3490:
struct addrinfo hints, *res; int sockfd; // first, load up address structs with getaddrinfo(): memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; // use IPv4 or IPv6, whichever hints.ai_socktype = SOCK_STREAM; hints.ai_flags = AI_PASSIVE; // fill in my IP for me getaddrinfo(NULL, "3490", &hints, &res); // make a socket: sockfd = socket(res->ai_family, res->ai_socktype, res->ai_protocol); // bind it to the port we passed in to getaddrinfo(): bind(sockfd, res->ai_addr, res->ai_addrlen);
By using the AI_PASSIVE flag, I'm telling the program to bind to the IP of the host it's running on. If you want to bind to a specific local IP address, drop the AI_PASSIVE and put an IP address in for the first argument to getaddrinfo().
bind() also returns -1 on error and sets errno to the error's value.
Lots of old code manually packs the
// !!! THIS IS THE OLD WAY !!! int sockfd; struct sockaddr_in my_addr; sockfd = socket(PF_INET, SOCK_STREAM, 0); my_addr.sin_family = AF_INET; my_addr.sin_port = htons(MYPORT); // short, network byte order my_addr.sin_addr.s_addr = inet_addr("10.12.110.57"); memset(my_addr.sin_zero, '\0', sizeof my_addr.sin_zero); bind(sockfd, (struct sockaddr *)&my_addr, sizeof my_addr);
In the above code, you could also assign INADDR_ANY to
the s_addr field if you wanted to bind to your local IP
address (like the AI_PASSIVE flag, above.) The IPv6
version of INADDR_ANY is a global variable
in6addr_any that is assigned into the sin6_addr
field of your
Another thing to watch out for when calling bind(): don't go underboard with your port numbers. All ports below 1024 are RESERVED (unless you're the superuser)! You can have any port number above that, right up to 65535 (provided they aren't already being used by another program.)
Sometimes, you might notice, you try to rerun a server and bind() fails, claiming "Address already in use." What does that mean? Well, a little bit of a socket that was connected is still hanging around in the kernel, and it's hogging the port. You can either wait for it to clear (a minute or so), or add code to your program allowing it to reuse the port, like this:
int yes=1; //char yes='1'; // Solaris people use this // lose the pesky "Address already in use" error message if (setsockopt(listener,SOL_SOCKET,SO_REUSEADDR,&yes,sizeof(int)) == -1) { perror("setsockopt"); exit(1); }
One small extra final note about bind(): there are times when you won't absolutely have to call it. If you are connect()ing to a remote machine and you don't care what your local port is (as is the case with telnet where you only care about the remote port), you can simply call connect(), it'll check to see if the socket is unbound, and will bind() it to an unused local port if necessary.
Let's just pretend for a few minutes that you're a telnet application. Your user commands you (just like in the movie TRON) to get a socket file descriptor. You comply and call socket(). Next, the user tells you to connect to "10.12.110.57" on port "23" (the standard telnet port.) Yow! What do you do now?
Lucky for you, program, you're now perusing the section on connect()—how to connect to a remote host. So read furiously onward! No time to lose!
The connect() call is as follows:
#include <sys/types.h> #include <sys/socket.h> int connect(int sockfd, struct sockaddr *serv_addr, int addrlen);
sockfd is our friendly neighborhood socket
file descriptor, as returned by the socket() call,
serv_addr is a
All of this information can be gleaned from the results of the getaddrinfo() call, which rocks.
Is this starting to make more sense? I can't hear you from here, so I'll just have to hope that it is. Let's have an example where we make a socket connection to "www.example.com", port 3490:
struct addrinfo hints, *res; int sockfd; // first, load up address structs with getaddrinfo(): memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; hints.ai_socktype = SOCK_STREAM; getaddrinfo("www.example.com", "3490", &hints, &res); // make a socket: sockfd = socket(res->ai_family, res->ai_socktype, res->ai_protocol); // connect! connect(sockfd, res->ai_addr, res->ai_addrlen);
Again, old-school programs filled out their own
Be sure to check the return value from connect()—it'll return -1 on error and set the variable errno.
Also, notice that we didn't call bind(). Basically, we don't care about our local port number; we only care where we're going (the remote port). The kernel will choose a local port for us, and the site we connect to will automatically get this information from us. No worries.
Ok, time for a change of pace. What if you don't want to connect to a remote host. Say, just for kicks, that you want to wait for incoming connections and handle them in some way. The process is two step: first you listen(), then you accept() (see below.)
The listen call is fairly simple, but requires a bit of explanation:
int listen(int sockfd, int backlog);
sockfd is the usual socket file descriptor from the socket() system call. backlog is the number of connections allowed on the incoming queue. What does that mean? Well, incoming connections are going to wait in this queue until you accept() them (see below) and this is the limit on how many can queue up. Most systems silently limit this number to about 20; you can probably get away with setting it to 5 or 10.
Again, as per usual, listen() returns -1 and sets errno on error.
Well, as you can probably imagine, we need to call bind() before we call listen() so that the server is running on a specific port. (You have to be able to tell your buddies which port to connect to!) So if you're going to be listening for incoming connections, the sequence of system calls you'll make is:
getaddrinfo(); socket(); bind(); listen(); /* accept() goes here */
I'll just leave that in the place of sample code, since it's fairly self-explanatory. (The code in the accept() section, below, is more complete.) The really tricky part of this whole sha-bang is the call to accept().
Get ready—the accept() call is kinda weird! What's going to happen is this: someone far far away will try to connect() to your machine on a port that you are listen()ing on. Their connection will be queued up waiting to be accept()ed. You call accept() and you tell it to get the pending connection. It'll return to you a brand new socket file descriptor to use for this single connection! That's right, suddenly you have two socket file descriptors for the price of one! The original one is still listening for more new connections, and the newly created one is finally ready to send() and recv(). We're there!
The call is as follows:
#include <sys/types.h> #include <sys/socket.h> int accept(int sockfd, struct sockaddr *addr, socklen_t *addrlen);
sockfd is the
listen()ing socket descriptor. Easy enough.
addr will usually be a pointer to a local
Guess what? accept() returns -1 and sets errno if an error occurs. Betcha didn't figure that.
Like before, this is a bunch to absorb in one chunk, so here's a sample code fragment for your perusal:
#include <string.h> #include <sys/types.h> #include <sys/socket.h> #include <netinet/in.h> #define MYPORT "3490" // the port users will be connecting to #define BACKLOG 10 // how many pending connections queue will hold int main(void) { struct sockaddr_storage their_addr; socklen_t addr_size; struct addrinfo hints, *res; int sockfd, new_fd; // !! don't forget your error checking for these calls !! // first, load up address structs with getaddrinfo(): memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; // use IPv4 or IPv6, whichever hints.ai_socktype = SOCK_STREAM; hints.ai_flags = AI_PASSIVE; // fill in my IP for me getaddrinfo(NULL, MYPORT, &hints, &res); // make a socket, bind it, and listen on it: sockfd = socket(res->ai_family, res->ai_socktype, res->ai_protocol); bind(sockfd, res->ai_addr, res->ai_addrlen); listen(sockfd, BACKLOG); // now accept an incoming connection: addr_size = sizeof their_addr; new_fd = accept(sockfd, (struct sockaddr *)&their_addr, &addr_size); // ready to communicate on socket descriptor new_fd! . . .
Again, note that we will use the socket descriptor new_fd for all send() and recv() calls. If you're only getting one single connection ever, you can close() the listening sockfd in order to prevent more incoming connections on the same port, if you so desire.
These two functions are for communicating over stream sockets or connected datagram sockets. If you want to use regular unconnected datagram sockets, you'll need to see the section on sendto() and recvfrom(), below.
int send(int sockfd, const void *msg, int len, int flags);
sockfd is the socket descriptor you want to send data to (whether it's the one returned by socket() or the one you got with accept().) msg is a pointer to the data you want to send, and len is the length of that data in bytes. Just set flags to 0. (See the send() man page for more information concerning flags.)
Some sample code might be:
char *msg = "Beej was here!"; int len, bytes_sent; . . . len = strlen(msg); bytes_sent = send(sockfd, msg, len, 0); . . .
send() returns the number of bytes actually sent out—this might be less than the number you told it to send! See, sometimes you tell it to send a whole gob of data and it just can't handle it. It'll fire off as much of the data as it can, and trust you to send the rest later. Remember, if the value returned by send() doesn't match the value in len, it's up to you to send the rest of the string. The good news is this: if the packet is small (less than 1K or so) it will probably manage to send the whole thing all in one go. Again, -1 is returned on error, and errno is set to the error number.
The recv() call is similar in many respects:
int recv(int sockfd, void *buf, int len, int flags);
sockfd is the socket descriptor to read from, buf is the buffer to read the information into, len is the maximum length of the buffer, and flags can again be set to 0. (See the recv() man page for flag information.)
recv() returns the number of bytes actually read into the buffer, or -1 on error (with errno set, accordingly.)
Wait! recv() can return 0. This can mean only one thing: the remote side has closed the connection on you! A return value of 0 is recv()'s way of letting you know this has occurred.
There, that was easy, wasn't it? You can now pass data back and forth on stream sockets! Whee! You're a Unix Network Programmer!
"This is all fine and dandy," I hear you saying, "but where does this leave me with unconnected datagram sockets?" No problemo, amigo. We have just the thing.
Since datagram sockets aren't connected to a remote host, guess which piece of information we need to give before we send a packet? That's right! The destination address! Here's the scoop:
int sendto(int sockfd, const void *msg, int len, unsigned int flags, const struct sockaddr *to, socklen_t tolen);
As you can see, this call is basically the same as the call to
send() with the addition of two other pieces of
information. to is a pointer to a
To get your hands on the destination address structure, you'll probably either get it from getaddrinfo(), or from recvfrom(), below, or you'll fill it out by hand.
Just like with send(), sendto() returns the number of bytes actually sent (which, again, might be less than the number of bytes you told it to send!), or -1 on error.
Equally similar are recv() and recvfrom(). The synopsis of recvfrom() is:
int recvfrom(int sockfd, void *buf, int len, unsigned int flags, struct sockaddr *from, int *fromlen);
Again, this is just like recv() with the
addition of a couple fields. from is a pointer to a
local
recvfrom() returns the number of bytes received, or -1 on error (with errno set accordingly.)
So, here's a question: why do we use
(So... here's another question: why isn't
Remember, if you connect() a datagram socket, you can then simply use send() and recv() for all your transactions. The socket itself is still a datagram socket and the packets still use UDP, but the socket interface will automatically add the destination and source information for you.
Whew! You've been send()ing and recv()ing data all day long, and you've had it. You're ready to close the connection on your socket descriptor. This is easy. You can just use the regular Unix file descriptor close() function:
close(sockfd);
This will prevent any more reads and writes to the socket. Anyone attempting to read or write the socket on the remote end will receive an error.
Just in case you want a little more control over how the socket closes, you can use the shutdown() function. It allows you to cut off communication in a certain direction, or both ways (just like close() does.) Synopsis:
int shutdown(int sockfd, int how);
sockfd is the socket file descriptor you want to shutdown, and how is one of the following:
0 |
Further receives are disallowed |
1 |
Further sends are disallowed |
2 |
Further sends and receives are disallowed (like close()) |
shutdown() returns 0 on success, and -1 on error (with errno set accordingly.)
If you deign to use shutdown() on unconnected datagram sockets, it will simply make the socket unavailable for further send() and recv() calls (remember that you can use these if you connect() your datagram socket.)
It's important to note that shutdown() doesn't actually close the file descriptor—it just changes its usability. To free a socket descriptor, you need to use close().
Nothing to it.
(Except to remember that if you're using Windows and Winsock that you should call closesocket() instead of close().)
It's so easy, I almost didn't give it its own section. But here it is anyway.
The function getpeername() will tell you who is at the other end of a connected stream socket. The synopsis:
#include <sys/socket.h> int getpeername(int sockfd, struct sockaddr *addr, int *addrlen);
sockfd is the descriptor of the connected
stream socket, addr is a pointer to a
The function returns -1 on error and sets errno accordingly.
Once you have their address, you can use inet_ntop(), getnameinfo(), or gethostbyaddr() to print or get more information. No, you can't get their login name. (Ok, ok. If the other computer is running an ident daemon, this is possible. This, however, is beyond the scope of this document. Check out RFC 1413 for more info.)
Even easier than getpeername() is the function gethostname(). It returns the name of the computer that your program is running on. The name can then be used by gethostbyname(), below, to determine the IP address of your local machine.
What could be more fun? I could think of a few things, but they don't pertain to socket programming. Anyway, here's the breakdown:
#include <unistd.h> int gethostname(char *hostname, size_t size);
The arguments are simple: hostname is a pointer to an array of chars that will contain the hostname upon the function's return, and size is the length in bytes of the hostname array.
The function returns 0 on successful completion, and -1 on error, setting errno as usual.
It's a client-server world, baby. Just about everything on the network deals with client processes talking to server processes and vice-versa. Take telnet, for instance. When you connect to a remote host on port 23 with telnet (the client), a program on that host (called telnetd, the server) springs to life. It handles the incoming telnet connection, sets you up with a login prompt, etc.
Client-Server Interaction.
The exchange of information between client and server is summarized in the above diagram.
Note that the client-server pair can speak SOCK_STREAM, SOCK_DGRAM, or anything else (as long as they're speaking the same thing.) Some good examples of client-server pairs are telnet/telnetd, ftp/ftpd, or Firefox/Apache. Every time you use ftp, there's a remote program, ftpd, that serves you.
Often, there will only be one server on a machine, and that server will handle multiple clients using fork(). The basic routine is: server will wait for a connection, accept() it, and fork() a child process to handle it. This is what our sample server does in the next section.
All this server does is send the string "Hello, world!" out over a stream connection. All you need to do to test this server is run it in one window, and telnet to it from another with:
$ telnet remotehostname 3490
where remotehostname is the name of the machine you're running it on.
/* ** server.c -- a stream socket server demo */ #include <stdio.h> #include <stdlib.h> #include <unistd.h> #include <errno.h> #include <string.h> #include <sys/types.h> #include <sys/socket.h> #include <netinet/in.h> #include <netdb.h> #include <arpa/inet.h> #include <sys/wait.h> #include <signal.h> #define PORT "3490" // the port users will be connecting to #define BACKLOG 10 // how many pending connections queue will hold void sigchld_handler(int s) { // waitpid() might overwrite errno, so we save and restore it: int saved_errno = errno; while(waitpid(-1, NULL, WNOHANG) > 0); errno = saved_errno; } // get sockaddr, IPv4 or IPv6: void *get_in_addr(struct sockaddr *sa) { if (sa->sa_family == AF_INET) { return &(((struct sockaddr_in*)sa)->sin_addr); } return &(((struct sockaddr_in6*)sa)->sin6_addr); } int main(void) { int sockfd, new_fd; // listen on sock_fd, new connection on new_fd struct addrinfo hints, *servinfo, *p; struct sockaddr_storage their_addr; // connector's address information socklen_t sin_size; struct sigaction sa; int yes=1; char s[INET6_ADDRSTRLEN]; int rv; memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; hints.ai_socktype = SOCK_STREAM; hints.ai_flags = AI_PASSIVE; // use my IP if ((rv = getaddrinfo(NULL, PORT, &hints, &servinfo)) != 0) { fprintf(stderr, "getaddrinfo: %s\n", gai_strerror(rv)); return 1; } // loop through all the results and bind to the first we can for(p = servinfo; p != NULL; p = p->ai_next) { if ((sockfd = socket(p->ai_family, p->ai_socktype, p->ai_protocol)) == -1) { perror("server: socket"); continue; } if (setsockopt(sockfd, SOL_SOCKET, SO_REUSEADDR, &yes, sizeof(int)) == -1) { perror("setsockopt"); exit(1); } if (bind(sockfd, p->ai_addr, p->ai_addrlen) == -1) { close(sockfd); perror("server: bind"); continue; } break; } freeaddrinfo(servinfo); // all done with this structure if (p == NULL) { fprintf(stderr, "server: failed to bind\n"); exit(1); } if (listen(sockfd, BACKLOG) == -1) { perror("listen"); exit(1); } sa.sa_handler = sigchld_handler; // reap all dead processes sigemptyset(&sa.sa_mask); sa.sa_flags = SA_RESTART; if (sigaction(SIGCHLD, &sa, NULL) == -1) { perror("sigaction"); exit(1); } printf("server: waiting for connections...\n"); while(1) { // main accept() loop sin_size = sizeof their_addr; new_fd = accept(sockfd, (struct sockaddr *)&their_addr, &sin_size); if (new_fd == -1) { perror("accept"); continue; } inet_ntop(their_addr.ss_family, get_in_addr((struct sockaddr *)&their_addr), s, sizeof s); printf("server: got connection from %s\n", s); if (!fork()) { // this is the child process close(sockfd); // child doesn't need the listener if (send(new_fd, "Hello, world!", 13, 0) == -1) perror("send"); close(new_fd); exit(0); } close(new_fd); // parent doesn't need this } return 0; }
In case you're curious, I have the code in one big main() function for (I feel) syntactic clarity. Feel free to split it into smaller functions if it makes you feel better.
(Also, this whole sigaction() thing might be new to you—that's ok. The code that's there is responsible for reaping zombie processes that appear as the fork()ed child processes exit. If you make lots of zombies and don't reap them, your system administrator will become agitated.)
You can get the data from this server by using the client listed in the next section.
This guy's even easier than the server. All this client does is connect to the host you specify on the command line, port 3490. It gets the string that the server sends.
/* ** client.c -- a stream socket client demo */ #include <stdio.h> #include <stdlib.h> #include <unistd.h> #include <errno.h> #include <string.h> #include <netdb.h> #include <sys/types.h> #include <netinet/in.h> #include <sys/socket.h> #include <arpa/inet.h> #define PORT "3490" // the port client will be connecting to #define MAXDATASIZE 100 // max number of bytes we can get at once // get sockaddr, IPv4 or IPv6: void *get_in_addr(struct sockaddr *sa) { if (sa->sa_family == AF_INET) { return &(((struct sockaddr_in*)sa)->sin_addr); } return &(((struct sockaddr_in6*)sa)->sin6_addr); } int main(int argc, char *argv[]) { int sockfd, numbytes; char buf[MAXDATASIZE]; struct addrinfo hints, *servinfo, *p; int rv; char s[INET6_ADDRSTRLEN]; if (argc != 2) { fprintf(stderr,"usage: client hostname\n"); exit(1); } memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; hints.ai_socktype = SOCK_STREAM; if ((rv = getaddrinfo(argv[1], PORT, &hints, &servinfo)) != 0) { fprintf(stderr, "getaddrinfo: %s\n", gai_strerror(rv)); return 1; } // loop through all the results and connect to the first we can for(p = servinfo; p != NULL; p = p->ai_next) { if ((sockfd = socket(p->ai_family, p->ai_socktype, p->ai_protocol)) == -1) { perror("client: socket"); continue; } if (connect(sockfd, p->ai_addr, p->ai_addrlen) == -1) { close(sockfd); perror("client: connect"); continue; } break; } if (p == NULL) { fprintf(stderr, "client: failed to connect\n"); return 2; } inet_ntop(p->ai_family, get_in_addr((struct sockaddr *)p->ai_addr), s, sizeof s); printf("client: connecting to %s\n", s); freeaddrinfo(servinfo); // all done with this structure if ((numbytes = recv(sockfd, buf, MAXDATASIZE-1, 0)) == -1) { perror("recv"); exit(1); } buf[numbytes] = '\0'; printf("client: received '%s'\n",buf); close(sockfd); return 0; }
Notice that if you don't run the server before you run the client, connect() returns "Connection refused". Very useful.
We've already covered the basics of UDP datagram sockets with our discussion of sendto() and recvfrom(), above, so I'll just present a couple of sample programs: talker.c and listener.c.
listener sits on a machine waiting for an incoming packet on port 4950. talker sends a packet to that port, on the specified machine, that contains whatever the user enters on the command line.
Here is the source for listener.c:
/* ** listener.c -- a datagram sockets "server" demo */ #include <stdio.h> #include <stdlib.h> #include <unistd.h> #include <errno.h> #include <string.h> #include <sys/types.h> #include <sys/socket.h> #include <netinet/in.h> #include <arpa/inet.h> #include <netdb.h> #define MYPORT "4950" // the port users will be connecting to #define MAXBUFLEN 100 // get sockaddr, IPv4 or IPv6: void *get_in_addr(struct sockaddr *sa) { if (sa->sa_family == AF_INET) { return &(((struct sockaddr_in*)sa)->sin_addr); } return &(((struct sockaddr_in6*)sa)->sin6_addr); } int main(void) { int sockfd; struct addrinfo hints, *servinfo, *p; int rv; int numbytes; struct sockaddr_storage their_addr; char buf[MAXBUFLEN]; socklen_t addr_len; char s[INET6_ADDRSTRLEN]; memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; // set to AF_INET to force IPv4 hints.ai_socktype = SOCK_DGRAM; hints.ai_flags = AI_PASSIVE; // use my IP if ((rv = getaddrinfo(NULL, MYPORT, &hints, &servinfo)) != 0) { fprintf(stderr, "getaddrinfo: %s\n", gai_strerror(rv)); return 1; } // loop through all the results and bind to the first we can for(p = servinfo; p != NULL; p = p->ai_next) { if ((sockfd = socket(p->ai_family, p->ai_socktype, p->ai_protocol)) == -1) { perror("listener: socket"); continue; } if (bind(sockfd, p->ai_addr, p->ai_addrlen) == -1) { close(sockfd); perror("listener: bind"); continue; } break; } if (p == NULL) { fprintf(stderr, "listener: failed to bind socket\n"); return 2; } freeaddrinfo(servinfo); printf("listener: waiting to recvfrom...\n"); addr_len = sizeof their_addr; if ((numbytes = recvfrom(sockfd, buf, MAXBUFLEN-1 , 0, (struct sockaddr *)&their_addr, &addr_len)) == -1) { perror("recvfrom"); exit(1); } printf("listener: got packet from %s\n", inet_ntop(their_addr.ss_family, get_in_addr((struct sockaddr *)&their_addr), s, sizeof s)); printf("listener: packet is %d bytes long\n", numbytes); buf[numbytes] = '\0'; printf("listener: packet contains \"%s\"\n", buf); close(sockfd); return 0; }
Notice that in our call to getaddrinfo() we're finally using SOCK_DGRAM. Also, note that there's no need to listen() or accept(). This is one of the perks of using unconnected datagram sockets!
Next comes the source for talker.c:
/* ** talker.c -- a datagram "client" demo */ #include <stdio.h> #include <stdlib.h> #include <unistd.h> #include <errno.h> #include <string.h> #include <sys/types.h> #include <sys/socket.h> #include <netinet/in.h> #include <arpa/inet.h> #include <netdb.h> #define SERVERPORT "4950" // the port users will be connecting to int main(int argc, char *argv[]) { int sockfd; struct addrinfo hints, *servinfo, *p; int rv; int numbytes; if (argc != 3) { fprintf(stderr,"usage: talker hostname message\n"); exit(1); } memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; hints.ai_socktype = SOCK_DGRAM; if ((rv = getaddrinfo(argv[1], SERVERPORT, &hints, &servinfo)) != 0) { fprintf(stderr, "getaddrinfo: %s\n", gai_strerror(rv)); return 1; } // loop through all the results and make a socket for(p = servinfo; p != NULL; p = p->ai_next) { if ((sockfd = socket(p->ai_family, p->ai_socktype, p->ai_protocol)) == -1) { perror("talker: socket"); continue; } break; } if (p == NULL) { fprintf(stderr, "talker: failed to create socket\n"); return 2; } if ((numbytes = sendto(sockfd, argv[2], strlen(argv[2]), 0, p->ai_addr, p->ai_addrlen)) == -1) { perror("talker: sendto"); exit(1); } freeaddrinfo(servinfo); printf("talker: sent %d bytes to %s\n", numbytes, argv[1]); close(sockfd); return 0; }
And that's all there is to it! Run listener on some machine, then run talker on another. Watch them communicate! Fun G-rated excitement for the entire nuclear family!
You don't even have to run the server this time! You can run talker by itself, and it just happily fires packets off into the ether where they disappear if no one is ready with a recvfrom() on the other side. Remember: data sent using UDP datagram sockets isn't guaranteed to arrive!
Except for one more tiny detail that I've mentioned many times in the past: connected datagram sockets. I need to talk about this here, since we're in the datagram section of the document. Let's say that talker calls connect() and specifies the listener's address. From that point on, talker may only sent to and receive from the address specified by connect(). For this reason, you don't have to use sendto() and recvfrom(); you can simply use send() and recv().
These aren't really advanced, but they're getting out of the more basic levels we've already covered. In fact, if you've gotten this far, you should consider yourself fairly accomplished in the basics of Unix network programming! Congratulations!
So here we go into the brave new world of some of the more esoteric things you might want to learn about sockets. Have at it!
Blocking. You've heard about it—now what the heck is it? In a nutshell, "block" is techie jargon for "sleep". You probably noticed that when you run listener, above, it just sits there until a packet arrives. What happened is that it called recvfrom(), there was no data, and so recvfrom() is said to "block" (that is, sleep there) until some data arrives.
Lots of functions block. accept() blocks. All the recv() functions block. The reason they can do this is because they're allowed to. When you first create the socket descriptor with socket(), the kernel sets it to blocking. If you don't want a socket to be blocking, you have to make a call to fcntl():
#include <unistd.h> #include <fcntl.h> . . . sockfd = socket(PF_INET, SOCK_STREAM, 0); fcntl(sockfd, F_SETFL, O_NONBLOCK); . . .
By setting a socket to non-blocking, you can effectively "poll" the socket for information. If you try to read from a non-blocking socket and there's no data there, it's not allowed to block—it will return -1 and errno will be set to EAGAIN or EWOULDBLOCK.
(Wait—it can return EAGAIN or EWOULDBLOCK? Which do you check for? The specification doesn't actually specify which your system will return, so for portability, check them both.)
Generally speaking, however, this type of polling is a bad idea. If you put your program in a busy-wait looking for data on the socket, you'll suck up CPU time like it was going out of style. A more elegant solution for checking to see if there's data waiting to be read comes in the following section on select().
This function is somewhat strange, but it's very useful. Take the following situation: you are a server and you want to listen for incoming connections as well as keep reading from the connections you already have.
No problem, you say, just an accept() and a couple of recv()s. Not so fast, buster! What if you're blocking on an accept() call? How are you going to recv() data at the same time? "Use non-blocking sockets!" No way! You don't want to be a CPU hog. What, then?
select() gives you the power to monitor several sockets at the same time. It'll tell you which ones are ready for reading, which are ready for writing, and which sockets have raised exceptions, if you really want to know that.
This being said, in modern times select(), though very portable, is one of the slowest methods for monitoring sockets. One possible alternative is libevent, or something similar, that encapsulates all the system-dependent stuff involved with getting socket notifications.
Without any further ado, I'll offer the synopsis of select():
#include <sys/time.h> #include <sys/types.h> #include <unistd.h> int select(int numfds, fd_set *readfds, fd_set *writefds, fd_set *exceptfds, struct timeval *timeout);
The function monitors "sets" of file descriptors; in particular readfds, writefds, and exceptfds. If you want to see if you can read from standard input and some socket descriptor, sockfd, just add the file descriptors 0 and sockfd to the set readfds. The parameter numfds should be set to the values of the highest file descriptor plus one. In this example, it should be set to sockfd+1, since it is assuredly higher than standard input (0).
When select() returns, readfds will be modified to reflect which of the file descriptors you selected which is ready for reading. You can test them with the macro FD_ISSET(), below.
Before progressing much further, I'll talk about how to manipulate
these sets. Each set is of the type
Add fd to the set. |
|
Remove fd from the set. |
|
Return true if fd is in the set. |
|
Clear all entries from the set. |
Finally, what is this weirded out
The
struct timeval { int tv_sec; // seconds int tv_usec; // microseconds };
Just set tv_sec to the number of seconds to wait, and set tv_usec to the number of microseconds to wait. Yes, that's microseconds, not milliseconds. There are 1,000 microseconds in a millisecond, and 1,000 milliseconds in a second. Thus, there are 1,000,000 microseconds in a second. Why is it "usec"? The "u" is supposed to look like the Greek letter μ (Mu) that we use for "micro". Also, when the function returns, timeout might be updated to show the time still remaining. This depends on what flavor of Unix you're running.
Yay! We have a microsecond resolution timer! Well, don't count on
it. You'll probably have to wait some part of your standard Unix
timeslice no matter how small you set your
Other things of interest: If you set the fields in your
The following code snippet waits 2.5 seconds for something to appear on standard input:
/* ** select.c -- a select() demo */ #include <stdio.h> #include <sys/time.h> #include <sys/types.h> #include <unistd.h> #define STDIN 0 // file descriptor for standard input int main(void) { struct timeval tv; fd_set readfds; tv.tv_sec = 2; tv.tv_usec = 500000; FD_ZERO(&readfds); FD_SET(STDIN, &readfds); // don't care about writefds and exceptfds: select(STDIN+1, &readfds, NULL, NULL, &tv); if (FD_ISSET(STDIN, &readfds)) printf("A key was pressed!\n"); else printf("Timed out.\n"); return 0; }
If you're on a line buffered terminal, the key you hit should be RETURN or it will time out anyway.
Now, some of you might think this is a great way to wait for data on a datagram socket—and you are right: it might be. Some Unices can use select in this manner, and some can't. You should see what your local man page says on the matter if you want to attempt it.
Some Unices update the time in your
What happens if a socket in the read set closes the connection? Well, in that case, select() returns with that socket descriptor set as "ready to read". When you actually do recv() from it, recv() will return 0. That's how you know the client has closed the connection.
One more note of interest about select(): if you have a socket that is listen()ing, you can check to see if there is a new connection by putting that socket's file descriptor in the readfds set.
And that, my friends, is a quick overview of the almighty select() function.
But, by popular demand, here is an in-depth example. Unfortunately, the difference between the dirt-simple example, above, and this one here is significant. But have a look, then read the description that follows it.
This program acts like a simple multi-user chat server. Start it running in one window, then telnet to it ("telnet hostname 9034") from multiple other windows. When you type something in one telnet session, it should appear in all the others.
/* ** selectserver.c -- a cheezy multiperson chat server */ #include <stdio.h> #include <stdlib.h> #include <string.h> #include <unistd.h> #include <sys/types.h> #include <sys/socket.h> #include <netinet/in.h> #include <arpa/inet.h> #include <netdb.h> #define PORT "9034" // port we're listening on // get sockaddr, IPv4 or IPv6: void *get_in_addr(struct sockaddr *sa) { if (sa->sa_family == AF_INET) { return &(((struct sockaddr_in*)sa)->sin_addr); } return &(((struct sockaddr_in6*)sa)->sin6_addr); } int main(void) { fd_set master; // master file descriptor list fd_set read_fds; // temp file descriptor list for select() int fdmax; // maximum file descriptor number int listener; // listening socket descriptor int newfd; // newly accept()ed socket descriptor struct sockaddr_storage remoteaddr; // client address socklen_t addrlen; char buf[256]; // buffer for client data int nbytes; char remoteIP[INET6_ADDRSTRLEN]; int yes=1; // for setsockopt() SO_REUSEADDR, below int i, j, rv; struct addrinfo hints, *ai, *p; FD_ZERO(&master); // clear the master and temp sets FD_ZERO(&read_fds); // get us a socket and bind it memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; hints.ai_socktype = SOCK_STREAM; hints.ai_flags = AI_PASSIVE; if ((rv = getaddrinfo(NULL, PORT, &hints, &ai)) != 0) { fprintf(stderr, "selectserver: %s\n", gai_strerror(rv)); exit(1); } for(p = ai; p != NULL; p = p->ai_next) { listener = socket(p->ai_family, p->ai_socktype, p->ai_protocol); if (listener < 0) { continue; } // lose the pesky "address already in use" error message setsockopt(listener, SOL_SOCKET, SO_REUSEADDR, &yes, sizeof(int)); if (bind(listener, p->ai_addr, p->ai_addrlen) < 0) { close(listener); continue; } break; } // if we got here, it means we didn't get bound if (p == NULL) { fprintf(stderr, "selectserver: failed to bind\n"); exit(2); } freeaddrinfo(ai); // all done with this // listen if (listen(listener, 10) == -1) { perror("listen"); exit(3); } // add the listener to the master set FD_SET(listener, &master); // keep track of the biggest file descriptor fdmax = listener; // so far, it's this one // main loop for(;;) { read_fds = master; // copy it if (select(fdmax+1, &read_fds, NULL, NULL, NULL) == -1) { perror("select"); exit(4); } // run through the existing connections looking for data to read for(i = 0; i <= fdmax; i++) { if (FD_ISSET(i, &read_fds)) { // we got one!! if (i == listener) { // handle new connections addrlen = sizeof remoteaddr; newfd = accept(listener, (struct sockaddr *)&remoteaddr, &addrlen); if (newfd == -1) { perror("accept"); } else { FD_SET(newfd, &master); // add to master set if (newfd > fdmax) { // keep track of the max fdmax = newfd; } printf("selectserver: new connection from %s on " "socket %d\n", inet_ntop(remoteaddr.ss_family, get_in_addr((struct sockaddr*)&remoteaddr), remoteIP, INET6_ADDRSTRLEN), newfd); } } else { // handle data from a client if ((nbytes = recv(i, buf, sizeof buf, 0)) <= 0) { // got error or connection closed by client if (nbytes == 0) { // connection closed printf("selectserver: socket %d hung up\n", i); } else { perror("recv"); } close(i); // bye! FD_CLR(i, &master); // remove from master set } else { // we got some data from a client for(j = 0; j <= fdmax; j++) { // send to everyone! if (FD_ISSET(j, &master)) { // except the listener and ourselves if (j != listener && j != i) { if (send(j, buf, nbytes, 0) == -1) { perror("send"); } } } } } } // END handle data from client } // END got new incoming connection } // END looping through file descriptors } // END for(;;)--and you thought it would never end! return 0; }
Notice I have two file descriptor sets in the code: master and read_fds. The first, master, holds all the socket descriptors that are currently connected, as well as the socket descriptor that is listening for new connections.
The reason I have the master set is that select() actually changes the set you pass into it to reflect which sockets are ready to read. Since I have to keep track of the connections from one call of select() to the next, I must store these safely away somewhere. At the last minute, I copy the master into the read_fds, and then call select().
But doesn't this mean that every time I get a new connection, I have to add it to the master set? Yup! And every time a connection closes, I have to remove it from the master set? Yes, it does.
Notice I check to see when the listener socket is ready to read. When it is, it means I have a new connection pending, and I accept() it and add it to the master set. Similarly, when a client connection is ready to read, and recv() returns 0, I know the client has closed the connection, and I must remove it from the master set.
If the client recv() returns non-zero, though, I know some data has been received. So I get it, and then go through the master list and send that data to all the rest of the connected clients.
And that, my friends, is a less-than-simple overview of the almighty select() function.
In addition, here is a bonus afterthought: there is another function called poll() which behaves much the same way select() does, but with a different system for managing the file descriptor sets. Check it out!
Remember back in the section about send(), above, when I said that send() might not send all the bytes you asked it to? That is, you want it to send 512 bytes, but it returns 412. What happened to the remaining 100 bytes?
Well, they're still in your little buffer waiting to be sent out. Due to circumstances beyond your control, the kernel decided not to send all the data out in one chunk, and now, my friend, it's up to you to get the data out there.
You could write a function like this to do it, too:
#include <sys/types.h> #include <sys/socket.h> int sendall(int s, char *buf, int *len) { int total = 0; // how many bytes we've sent int bytesleft = *len; // how many we have left to send int n; while(total < *len) { n = send(s, buf+total, bytesleft, 0); if (n == -1) { break; } total += n; bytesleft -= n; } *len = total; // return number actually sent here return n==-1?-1:0; // return -1 on failure, 0 on success }
In this example, s is the socket you want
to send the data to, buf is the buffer containing
the data, and len is a pointer to an
The function returns -1 on error (and errno is still set from the call to send().) Also, the number of bytes actually sent is returned in len. This will be the same number of bytes you asked it to send, unless there was an error. sendall() will do it's best, huffing and puffing, to send the data out, but if there's an error, it gets back to you right away.
For completeness, here's a sample call to the function:
char buf[10] = "Beej!"; int len; len = strlen(buf); if (sendall(s, buf, &len) == -1) { perror("sendall"); printf("We only sent %d bytes because of the error!\n", len); }
What happens on the receiver's end when part of a packet arrives? If the packets are variable length, how does the receiver know when one packet ends and another begins? Yes, real-world scenarios are a royal pain in the donkeys. You probably have to encapsulate (remember that from the data encapsulation section way back there at the beginning?) Read on for details!
It's easy enough to send text data across
the network, you're finding, but what happens if you want to send some
"binary" data like
Sneak preview! Tonight only!
[Curtain raises]
Beej says, "I prefer Method Three, above!"
[THE END]
(Before I begin this section in earnest, I should tell you that there are libraries out there for doing this, and rolling your own and remaining portable and error-free is quite a challenge. So hunt around and do your homework before deciding to implement this stuff yourself. I include the information here for those curious about how things like this work.)
Actually all the methods, above, have their drawbacks and advantages, but, like I said, in general, I prefer the third method. First, though, let's talk about some of the drawbacks and advantages to the other two.
The first method, encoding the numbers as text before sending, has the advantage that you can easily print and read the data that's coming over the wire. Sometimes a human-readable protocol is excellent to use in a non-bandwidth-intensive situation, such as with Internet Relay Chat (IRC). However, it has the disadvantage that it is slow to convert, and the results almost always take up more space than the original number!
Method two: passing the raw data. This one is quite easy (but dangerous!): just take a pointer to the data to send, and call send with it.
double d = 3490.15926535; send(s, &d, sizeof d, 0); /* DANGER--non-portable! */
The receiver gets it like this:
double d; recv(s, &d, sizeof d, 0); /* DANGER--non-portable! */
Fast, simple—what's not to like? Well, it turns out that not
all architectures represent a
When packing integer types, we've already seen how the htons()-class of functions can help keep
things portable by transforming the numbers into
Network Byte Order, and how that's the Right Thing to do.
Unfortunately, there are no similar functions for
Fear not! (Were you afraid there for a second? No? Not even a little bit?) There is something we can do: we can pack (or "marshal", or "serialize", or one of a thousand million other names) the data into a known binary format that the receiver can unpack on the remote side.
What do I mean by "known binary format"? Well, we've already seen the htons() example, right? It changes (or "encodes", if you want to think of it that way) a number from whatever the host format is into Network Byte Order. To reverse (unencode) the number, the receiver calls ntohs().
But didn't I just get finished saying there wasn't any such function for other non-integer types? Yes. I did. And since there's no standard way in C to do this, it's a bit of a pickle (that a gratuitous pun there for you Python fans).
The thing to do is to pack the data into a known format and send that
over the wire for decoding. For example, to pack
#include <stdint.h> uint32_t htonf(float f) { uint32_t p; uint32_t sign; if (f < 0) { sign = 1; f = -f; } else { sign = 0; } p = ((((uint32_t)f)&0x7fff)<<16) | (sign<<31); // whole part and sign p |= (uint32_t)(((f - (int)f) * 65536.0f))&0xffff; // fraction return p; } float ntohf(uint32_t p) { float f = ((p>>16)&0x7fff); // whole part f += (p&0xffff) / 65536.0f; // fraction if (((p>>31)&0x1) == 0x1) { f = -f; } // sign bit set return f; }
The above code is sort of a naive implementation that stores a
Usage is fairly straightforward:
#include <stdio.h> int main(void) { float f = 3.1415926, f2; uint32_t netf; netf = htonf(f); // convert to "network" form f2 = ntohf(netf); // convert back to test printf("Original: %f\n", f); // 3.141593 printf(" Network: 0x%08X\n", netf); // 0x0003243F printf("Unpacked: %f\n", f2); // 3.141586 return 0; }
On the plus side, it's small, simple, and fast. On the minus side, it's not an efficient use of space and the range is severely restricted—try storing a number greater-than 32767 in there and it won't be very happy! You can also see in the above example that the last couple decimal places are not correctly preserved.
What can we do instead? Well, The Standard for storing floating point numbers is known as IEEE-754. Most computers use this format internally for doing floating point math, so in those cases, strictly speaking, conversion wouldn't need to be done. But if you want your source code to be portable, that's an assumption you can't necessarily make. (On the other hand, if you want things to be fast, you should optimize this out on platforms that don't need to do it! That's what htons() and its ilk do.)
Here's some code that encodes floats and doubles into IEEE-754 format. (Mostly—it doesn't encode NaN or Infinity, but it could be modified to do that.)
#define pack754_32(f) (pack754((f), 32, 8)) #define pack754_64(f) (pack754((f), 64, 11)) #define unpack754_32(i) (unpack754((i), 32, 8)) #define unpack754_64(i) (unpack754((i), 64, 11)) uint64_t pack754(long double f, unsigned bits, unsigned expbits) { long double fnorm; int shift; long long sign, exp, significand; unsigned significandbits = bits - expbits - 1; // -1 for sign bit if (f == 0.0) return 0; // get this special case out of the way // check sign and begin normalization if (f < 0) { sign = 1; fnorm = -f; } else { sign = 0; fnorm = f; } // get the normalized form of f and track the exponent shift = 0; while(fnorm >= 2.0) { fnorm /= 2.0; shift++; } while(fnorm < 1.0) { fnorm *= 2.0; shift--; } fnorm = fnorm - 1.0; // calculate the binary form (non-float) of the significand data significand = fnorm * ((1LL<<significandbits) + 0.5f); // get the biased exponent exp = shift + ((1<<(expbits-1)) - 1); // shift + bias // return the final answer return (sign<<(bits-1)) | (exp<<(bits-expbits-1)) | significand; } long double unpack754(uint64_t i, unsigned bits, unsigned expbits) { long double result; long long shift; unsigned bias; unsigned significandbits = bits - expbits - 1; // -1 for sign bit if (i == 0) return 0.0; // pull the significand result = (i&((1LL<<significandbits)-1)); // mask result /= (1LL<<significandbits); // convert back to float result += 1.0f; // add the one back on // deal with the exponent bias = (1<<(expbits-1)) - 1; shift = ((i>>significandbits)&((1LL<<expbits)-1)) - bias; while(shift > 0) { result *= 2.0; shift--; } while(shift < 0) { result /= 2.0; shift++; } // sign it result *= (i>>(bits-1))&1? -1.0: 1.0; return result; }
I put some handy macros up there at the top for packing and unpacking
32-bit (probably a
Here's sample usage:
#include <stdio.h> #include <stdint.h> // defines uintN_t types #include <inttypes.h> // defines PRIx macros int main(void) { float f = 3.1415926, f2; double d = 3.14159265358979323, d2; uint32_t fi; uint64_t di; fi = pack754_32(f); f2 = unpack754_32(fi); di = pack754_64(d); d2 = unpack754_64(di); printf("float before : %.7f\n", f); printf("float encoded: 0x%08" PRIx32 "\n", fi); printf("float after : %.7f\n\n", f2); printf("double before : %.20lf\n", d); printf("double encoded: 0x%016" PRIx64 "\n", di); printf("double after : %.20lf\n", d2); return 0; }
The above code produces this output:
float before : 3.1415925 float encoded: 0x40490FDA float after : 3.1415925 double before : 3.14159265358979311600 double encoded: 0x400921FB54442D18 double after : 3.14159265358979311600
Another question you might have is how do you pack
Back to it: the best way to send the
That's a lot of work, is what you're thinking. Yes, it is. One thing you can do is write a helper function to help pack the data for you. It'll be fun! Really!
In the book "The Practice of Programming" by Kernighan and Pike, they implement printf()-like functions called pack() and unpack() that do exactly this. I'd link to them, but apparently those functions aren't online with the rest of the source from the book.
(The Practice of Programming is an excellent read. Zeus saves a kitten every time I recommend it.)
At this point, I'm going to drop a pointer to the BSD-licensed Typed Parameter Language C API which I've never used, but looks completely respectable. Python and Perl programmers will want to check out their language's pack() and unpack() functions for accomplishing the same thing. And Java has a big-ol' Serializable interface that can be used in a similar way.
But if you want to write your own packing utility in C, K&P's trick is to use variable argument lists to make printf()-like functions to build the packets. Here's a version I cooked up on my own based on that which hopefully will be enough to give you an idea of how such a thing can work.
(This code references the pack754() functions, above.
The packi*() functions operate like the familiar
htons() family, except they pack into a
#include <stdio.h> #include <ctype.h> #include <stdarg.h> #include <string.h> /* ** packi16() -- store a 16-bit int into a char buffer (like htons()) */ void packi16(unsigned char *buf, unsigned int i) { *buf++ = i>>8; *buf++ = i; } /* ** packi32() -- store a 32-bit int into a char buffer (like htonl()) */ void packi32(unsigned char *buf, unsigned long int i) { *buf++ = i>>24; *buf++ = i>>16; *buf++ = i>>8; *buf++ = i; } /* ** packi64() -- store a 64-bit int into a char buffer (like htonl()) */ void packi64(unsigned char *buf, unsigned long long int i) { *buf++ = i>>56; *buf++ = i>>48; *buf++ = i>>40; *buf++ = i>>32; *buf++ = i>>24; *buf++ = i>>16; *buf++ = i>>8; *buf++ = i; } /* ** unpacki16() -- unpack a 16-bit int from a char buffer (like ntohs()) */ int unpacki16(unsigned char *buf) { unsigned int i2 = ((unsigned int)buf[0]<<8) | buf[1]; int i; // change unsigned numbers to signed if (i2 <= 0x7fffu) { i = i2; } else { i = -1 - (unsigned int)(0xffffu - i2); } return i; } /* ** unpacku16() -- unpack a 16-bit unsigned from a char buffer (like ntohs()) */ unsigned int unpacku16(unsigned char *buf) { return ((unsigned int)buf[0]<<8) | buf[1]; } /* ** unpacki32() -- unpack a 32-bit int from a char buffer (like ntohl()) */ long int unpacki32(unsigned char *buf) { unsigned long int i2 = ((unsigned long int)buf[0]<<24) | ((unsigned long int)buf[1]<<16) | ((unsigned long int)buf[2]<<8) | buf[3]; long int i; // change unsigned numbers to signed if (i2 <= 0x7fffffffu) { i = i2; } else { i = -1 - (long int)(0xffffffffu - i2); } return i; } /* ** unpacku32() -- unpack a 32-bit unsigned from a char buffer (like ntohl()) */ unsigned long int unpacku32(unsigned char *buf) { return ((unsigned long int)buf[0]<<24) | ((unsigned long int)buf[1]<<16) | ((unsigned long int)buf[2]<<8) | buf[3]; } /* ** unpacki64() -- unpack a 64-bit int from a char buffer (like ntohl()) */ long long int unpacki64(unsigned char *buf) { unsigned long long int i2 = ((unsigned long long int)buf[0]<<56) | ((unsigned long long int)buf[1]<<48) | ((unsigned long long int)buf[2]<<40) | ((unsigned long long int)buf[3]<<32) | ((unsigned long long int)buf[4]<<24) | ((unsigned long long int)buf[5]<<16) | ((unsigned long long int)buf[6]<<8) | buf[7]; long long int i; // change unsigned numbers to signed if (i2 <= 0x7fffffffffffffffu) { i = i2; } else { i = -1 -(long long int)(0xffffffffffffffffu - i2); } return i; } /* ** unpacku64() -- unpack a 64-bit unsigned from a char buffer (like ntohl()) */ unsigned long long int unpacku64(unsigned char *buf) { return ((unsigned long long int)buf[0]<<56) | ((unsigned long long int)buf[1]<<48) | ((unsigned long long int)buf[2]<<40) | ((unsigned long long int)buf[3]<<32) | ((unsigned long long int)buf[4]<<24) | ((unsigned long long int)buf[5]<<16) | ((unsigned long long int)buf[6]<<8) | buf[7]; } /* ** pack() -- store data dictated by the format string in the buffer ** ** bits |signed unsigned float string ** -----+---------------------------------- ** 8 | c C ** 16 | h H f ** 32 | l L d ** 64 | q Q g ** - | s ** ** (16-bit unsigned length is automatically prepended to strings) */ unsigned int pack(unsigned char *buf, char *format, ...) { va_list ap; signed char c; // 8-bit unsigned char C; int h; // 16-bit unsigned int H; long int l; // 32-bit unsigned long int L; long long int q; // 64-bit unsigned long long int Q; float f; // floats double d; long double g; unsigned long long int fhold; char *s; // strings unsigned int len; unsigned int size = 0; va_start(ap, format); for(; *format != '\0'; format++) { switch(*format) { case 'c': // 8-bit size += 1; c = (signed char)va_arg(ap, int); // promoted *buf++ = c; break; case 'C': // 8-bit unsigned size += 1; C = (unsigned char)va_arg(ap, unsigned int); // promoted *buf++ = C; break; case 'h': // 16-bit size += 2; h = va_arg(ap, int); packi16(buf, h); buf += 2; break; case 'H': // 16-bit unsigned size += 2; H = va_arg(ap, unsigned int); packi16(buf, H); buf += 2; break; case 'l': // 32-bit size += 4; l = va_arg(ap, long int); packi32(buf, l); buf += 4; break; case 'L': // 32-bit unsigned size += 4; L = va_arg(ap, unsigned long int); packi32(buf, L); buf += 4; break; case 'q': // 64-bit size += 8; q = va_arg(ap, long long int); packi64(buf, q); buf += 8; break; case 'Q': // 64-bit unsigned size += 8; Q = va_arg(ap, unsigned long long int); packi64(buf, Q); buf += 8; break; case 'f': // float-16 size += 2; f = (float)va_arg(ap, double); // promoted fhold = pack754_16(f); // convert to IEEE 754 packi16(buf, fhold); buf += 2; break; case 'd': // float-32 size += 4; d = va_arg(ap, double); fhold = pack754_32(d); // convert to IEEE 754 packi32(buf, fhold); buf += 4; break; case 'g': // float-64 size += 8; g = va_arg(ap, long double); fhold = pack754_64(g); // convert to IEEE 754 packi64(buf, fhold); buf += 8; break; case 's': // string s = va_arg(ap, char*); len = strlen(s); size += len + 2; packi16(buf, len); buf += 2; memcpy(buf, s, len); buf += len; break; } } va_end(ap); return size; } /* ** unpack() -- unpack data dictated by the format string into the buffer ** ** bits |signed unsigned float string ** -----+---------------------------------- ** 8 | c C ** 16 | h H f ** 32 | l L d ** 64 | q Q g ** - | s ** ** (string is extracted based on its stored length, but 's' can be ** prepended with a max length) */ void unpack(unsigned char *buf, char *format, ...) { va_list ap; signed char *c; // 8-bit unsigned char *C; int *h; // 16-bit unsigned int *H; long int *l; // 32-bit unsigned long int *L; long long int *q; // 64-bit unsigned long long int *Q; float *f; // floats double *d; long double *g; unsigned long long int fhold; char *s; unsigned int len, maxstrlen=0, count; va_start(ap, format); for(; *format != '\0'; format++) { switch(*format) { case 'c': // 8-bit c = va_arg(ap, signed char*); if (*buf <= 0x7f) { *c = *buf;} // re-sign else { *c = -1 - (unsigned char)(0xffu - *buf); } buf++; break; case 'C': // 8-bit unsigned C = va_arg(ap, unsigned char*); *C = *buf++; break; case 'h': // 16-bit h = va_arg(ap, int*); *h = unpacki16(buf); buf += 2; break; case 'H': // 16-bit unsigned H = va_arg(ap, unsigned int*); *H = unpacku16(buf); buf += 2; break; case 'l': // 32-bit l = va_arg(ap, long int*); *l = unpacki32(buf); buf += 4; break; case 'L': // 32-bit unsigned L = va_arg(ap, unsigned long int*); *L = unpacku32(buf); buf += 4; break; case 'q': // 64-bit q = va_arg(ap, long long int*); *q = unpacki64(buf); buf += 8; break; case 'Q': // 64-bit unsigned Q = va_arg(ap, unsigned long long int*); *Q = unpacku64(buf); buf += 8; break; case 'f': // float f = va_arg(ap, float*); fhold = unpacku16(buf); *f = unpack754_16(fhold); buf += 2; break; case 'd': // float-32 d = va_arg(ap, double*); fhold = unpacku32(buf); *d = unpack754_32(fhold); buf += 4; break; case 'g': // float-64 g = va_arg(ap, long double*); fhold = unpacku64(buf); *g = unpack754_64(fhold); buf += 8; break; case 's': // string s = va_arg(ap, char*); len = unpacku16(buf); buf += 2; if (maxstrlen > 0 && len > maxstrlen) count = maxstrlen - 1; else count = len; memcpy(s, buf, count); s[count] = '\0'; buf += len; break; default: if (isdigit(*format)) { // track max str len maxstrlen = maxstrlen * 10 + (*format-'0'); } } if (!isdigit(*format)) maxstrlen = 0; } va_end(ap); }
And here is a demonstration program of the above code that packs some data into buf and then unpacks it into variables. Note that when calling unpack() with a string argument (format specifier "s"), it's wise to put a maximum length count in front of it to prevent a buffer overrun, e.g. "96s". Be wary when unpacking data you get over the network—a malicious user might send badly-constructed packets in an effort to attack your system!
#include <stdio.h> // various bits for floating point types-- // varies for different architectures typedef float float32_t; typedef double float64_t; int main(void) { unsigned char buf[1024]; int8_t magic; int16_t monkeycount; int32_t altitude; float32_t absurdityfactor; char *s = "Great unmitigated Zot! You've found the Runestaff!"; char s2[96]; int16_t packetsize, ps2; packetsize = pack(buf, "chhlsf", (int8_t)'B', (int16_t)0, (int16_t)37, (int32_t)-5, s, (float32_t)-3490.6677); packi16(buf+1, packetsize); // store packet size in packet for kicks printf("packet is %" PRId32 " bytes\n", packetsize); unpack(buf, "chhl96sf", &magic, &ps2, &monkeycount, &altitude, s2, &absurdityfactor); printf("'%c' %" PRId32" %" PRId16 " %" PRId32 " \"%s\" %f\n", magic, ps2, monkeycount, altitude, s2, absurdityfactor); return 0; }
Whether you roll your own code or use someone else's, it's a good idea to have a general set of data packing routines for the sake of keeping bugs in check, rather than packing each bit by hand each time.
When packing the data, what's a good format to use? Excellent question. Fortunately, RFC 4506, the External Data Representation Standard, already defines binary formats for a bunch of different types, like floating point types, integer types, arrays, raw data, etc. I suggest conforming to that if you're going to roll the data yourself. But you're not obligated to. The Packet Police are not right outside your door. At least, I don't think they are.
In any case, encoding the data somehow or another before you send it is the right way of doing things!
What does it really mean to encapsulate data, anyway? In the simplest case, it means you'll stick a header on there with either some identifying information or a packet length, or both.
What should your header look like? Well, it's just some binary data that represents whatever you feel is necessary to complete your project.
Wow. That's vague.
Okay. For instance, let's say you have a multi-user chat program that uses SOCK_STREAMs. When a user types ("says") something, two pieces of information need to be transmitted to the server: what was said and who said it.
So far so good? "What's the problem?" you're asking.
The problem is that the messages can be of varying lengths. One person named "tom" might say, "Hi", and another person named "Benjamin" might say, "Hey guys what is up?"
So you send() all this stuff to the clients as it comes in. Your outgoing data stream looks like this:
t o m H i B e n j a m i n H e y g u y s w h a t i s u p ?
And so on. How does the client know when one message starts and another stops? You could, if you wanted, make all messages the same length and just call the sendall() we implemented, above. But that wastes bandwidth! We don't want to send() 1024 bytes just so "tom" can say "Hi".
So we encapsulate the data in a tiny header and packet structure. Both the client and server know how to pack and unpack (sometimes referred to as "marshal" and "unmarshal") this data. Don't look now, but we're starting to define a protocol that describes how a client and server communicate!
In this case, let's assume the user name is a fixed length of 8 characters, padded with '\0'. And then let's assume the data is variable length, up to a maximum of 128 characters. Let's have a look a sample packet structure that we might use in this situation:
Why did I choose the 8-byte and 128-byte limits for the fields? I pulled them out of the air, assuming they'd be long enough. Maybe, though, 8 bytes is too restrictive for your needs, and you can have a 30-byte name field, or whatever. The choice is up to you.
Using the above packet definition, the first packet would consist of the following information (in hex and ASCII):
0A 74 6F 6D 00 00 00 00 00 48 69 (length) T o m (padding) H i
And the second is similar:
18 42 65 6E 6A 61 6D 69 6E 48 65 79 20 67 75 79 73 20 77 ... (length) B e n j a m i n H e y g u y s w ...
(The length is stored in Network Byte Order, of course. In this case, it's only one byte so it doesn't matter, but generally speaking you'll want all your binary integers to be stored in Network Byte Order in your packets.)
When you're sending this data, you should be safe and use a command similar to sendall(), above, so you know all the data is sent, even if it takes multiple calls to send() to get it all out.
Likewise, when you're receiving this data, you need to do a bit of extra work. To be safe, you should assume that you might receive a partial packet (like maybe we receive "18 42 65 6E 6A" from Benjamin, above, but that's all we get in this call to recv()). We need to call recv() over and over again until the packet is completely received.
But how? Well, we know the number of bytes we need to receive in total for the packet to be complete, since that number is tacked on the front of the packet. We also know the maximum packet size is 1+8+128, or 137 bytes (because that's how we defined the packet.)
There are actually a couple things you can do here. Since you know every packet starts off with a length, you can call recv() just to get the packet length. Then once you have that, you can call it again specifying exactly the remaining length of the packet (possibly repeatedly to get all the data) until you have the complete packet. The advantage of this method is that you only need a buffer large enough for one packet, while the disadvantage is that you need to call recv() at least twice to get all the data.
Another option is just to call recv() and say the amount you're willing to receive is the maximum number of bytes in a packet. Then whatever you get, stick it onto the back of a buffer, and finally check to see if the packet is complete. Of course, you might get some of the next packet, so you'll need to have room for that.
What you can do is declare an array big enough for two packets. This is your work array where you will reconstruct packets as they arrive.
Every time you recv() data, you'll append it into the work buffer and check to see if the packet is complete. That is, the number of bytes in the buffer is greater than or equal to the length specified in the header (+1, because the length in the header doesn't include the byte for the length itself.) If the number of bytes in the buffer is less than 1, the packet is not complete, obviously. You have to make a special case for this, though, since the first byte is garbage and you can't rely on it for the correct packet length.
Once the packet is complete, you can do with it what you will. Use it, and remove it from your work buffer.
Whew! Are you juggling that in your head yet? Well, here's the second of the one-two punch: you might have read past the end of one packet and onto the next in a single recv() call. That is, you have a work buffer with one complete packet, and an incomplete part of the next packet! Bloody heck. (But this is why you made your work buffer large enough to hold two packets—in case this happened!)
Since you know the length of the first packet from the header, and you've been keeping track of the number of bytes in the work buffer, you can subtract and calculate how many of the bytes in the work buffer belong to the second (incomplete) packet. When you've handled the first one, you can clear it out of the work buffer and move the partial second packet down the to front of the buffer so it's all ready to go for the next recv().
(Some of you readers will note that actually moving the partial second packet to the beginning of the work buffer takes time, and the program can be coded to not require this by using a circular buffer. Unfortunately for the rest of you, a discussion on circular buffers is beyond the scope of this article. If you're still curious, grab a data structures book and go from there.)
I never said it was easy. Ok, I did say it was easy. And it is; you just need practice and pretty soon it'll come to you naturally. By Excalibur I swear it!
So far, this guide has talked about sending data from one host to one other host. But it is possible, I insist, that you can, with the proper authority, send data to multiple hosts at the same time!
With UDP (only UDP, not TCP) and standard IPv4, this is done through a mechanism called broadcasting. With IPv6, broadcasting isn't supported, and you have to resort to the often superior technique of multicasting, which, sadly I won't be discussing at this time. But enough of the starry-eyed future—we're stuck in the 32-bit present.
But wait! You can't just run off and start broadcasting willy-nilly; You have to set the socket option SO_BROADCAST before you can send a broadcast packet out on the network. It's like a one of those little plastic covers they put over the missile launch switch! That's just how much power you hold in your hands!
But seriously, though, there is a danger to using broadcast packets, and that is: every system that receives a broadcast packet must undo all the onion-skin layers of data encapsulation until it finds out what port the data is destined to. And then it hands the data over or discards it. In either case, it's a lot of work for each machine that receives the broadcast packet, and since it is all of them on the local network, that could be a lot of machines doing a lot of unnecessary work. When the game Doom first came out, this was a complaint about its network code.
Now, there is more than one way to skin a cat... wait a minute. Is there really more than one way to skin a cat? What kind of expression is that? Uh, and likewise, there is more than one way to send a broadcast packet. So, to get to the meat and potatoes of the whole thing: how do you specify the destination address for a broadcast message? There are two common ways:
So what happens if you try to send data on the broadcast address without first setting the SO_BROADCAST socket option? Well, let's fire up good old talker and listener and see what happens.
$ talker 192.168.1.2 foo sent 3 bytes to 192.168.1.2 $ talker 192.168.1.255 foo sendto: Permission denied $ talker 255.255.255.255 foo sendto: Permission denied
Yes, it's not happy at all...because we didn't set the SO_BROADCAST socket option. Do that, and now you can sendto() anywhere you want!
In fact, that's the only difference between a UDP application that can broadcast and one that can't. So let's take the old talker application and add one section that sets the SO_BROADCAST socket option. We'll call this program broadcaster.c:
/* ** broadcaster.c -- a datagram "client" like talker.c, except ** this one can broadcast */ #include <stdio.h> #include <stdlib.h> #include <unistd.h> #include <errno.h> #include <string.h> #include <sys/types.h> #include <sys/socket.h> #include <netinet/in.h> #include <arpa/inet.h> #include <netdb.h> #define SERVERPORT 4950 // the port users will be connecting to int main(int argc, char *argv[]) { int sockfd; struct sockaddr_in their_addr; // connector's address information struct hostent *he; int numbytes; int broadcast = 1; //char broadcast = '1'; // if that doesn't work, try this if (argc != 3) { fprintf(stderr,"usage: broadcaster hostname message\n"); exit(1); } if ((he=gethostbyname(argv[1])) == NULL) { // get the host info perror("gethostbyname"); exit(1); } if ((sockfd = socket(AF_INET, SOCK_DGRAM, 0)) == -1) { perror("socket"); exit(1); } // this call is what allows broadcast packets to be sent: if (setsockopt(sockfd, SOL_SOCKET, SO_BROADCAST, &broadcast, sizeof broadcast) == -1) { perror("setsockopt (SO_BROADCAST)"); exit(1); } their_addr.sin_family = AF_INET; // host byte order their_addr.sin_port = htons(SERVERPORT); // short, network byte order their_addr.sin_addr = *((struct in_addr *)he->h_addr); memset(their_addr.sin_zero, '\0', sizeof their_addr.sin_zero); if ((numbytes=sendto(sockfd, argv[2], strlen(argv[2]), 0, (struct sockaddr *)&their_addr, sizeof their_addr)) == -1) { perror("sendto"); exit(1); } printf("sent %d bytes to %s\n", numbytes, inet_ntoa(their_addr.sin_addr)); close(sockfd); return 0; }
What's different between this and a "normal" UDP client/server situation? Nothing! (With the exception of the client being allowed to send broadcast packets in this case.) As such, go ahead and run the old UDP listener program in one window, and broadcaster in another. You should be now be able to do all those sends that failed, above.
$ broadcaster 192.168.1.2 foo sent 3 bytes to 192.168.1.2 $ broadcaster 192.168.1.255 foo sent 3 bytes to 192.168.1.255 $ broadcaster 255.255.255.255 foo sent 3 bytes to 255.255.255.255
And you should see listener responding that it got the packets. (If listener doesn't respond, it could be because it's bound to an IPv6 address. Try changing the AF_UNSPEC in listener.c to AF_INET to force IPv4.)
Well, that's kind of exciting. But now fire up listener on another machine next to you on the same network so that you have two copies going, one on each machine, and run broadcaster again with your broadcast address... Hey! Both listeners get the packet even though you only called sendto() once! Cool!
If the listener gets data you send directly to it, but not data on the broadcast address, it could be that you have a firewall on your local machine that is blocking the packets. (Yes, Pat and Bapper, thank you for realizing before I did that this is why my sample code wasn't working. I told you I'd mention you in the guide, and here you are. So nyah.)
Again, be careful with broadcast packets. Since every machine on the LAN will be forced to deal with the packet whether it recvfrom()s it or not, it can present quite a load to the entire computing network. They are definitely to be used sparingly and appropriately.
If you don't have them on your system already, you probably don't need them. Check the manual for your particular platform. If you're building for Windows, you only need to #include <winsock.h>.
You have to use setsockopt() with the SO_REUSEADDR option on the listening socket. Check out the section on bind() and the section on select() for an example.
Use the netstat. Check the man page for full details, but you should get some good output just typing:
$ netstat
The only trick is determining which socket is associated with which program. :-)
Run the route command (in /sbin on most Linuxes) or the command netstat -r.
Fortunately for you, virtually all machines implement a loopback network "device" that sits in the kernel and pretends to be a network card. (This is the interface listed as "lo" in the routing table.)
Pretend you're logged into a machine named "goat". Run the client in one window and the server in another. Or start the server in the background ("server &") and run the client in the same window. The upshot of the loopback device is that you can either client goat or client localhost (since "localhost" is likely defined in your /etc/hosts file) and you'll have the client talking to the server without a network!
In short, no changes are necessary to any of the code to make it run on a single non-networked machine! Huzzah!
You can tell because recv() will return 0.
All your raw sockets questions will be answered in W. Richard Stevens' UNIX Network Programming books. Also, look in the ping/ subdirectory in Stevens' UNIX Network Programming source code, available online.
Instead of giving you exactly the same answer that W. Richard Stevens would give you, I'll just refer you to lib/connect_nonb.c in the UNIX Network Programming source code.
The gist of it is that you make a socket descriptor with socket(), set it to non-blocking, call connect(), and if all goes well connect() will return -1 immediately and errno will be set to EINPROGRESS. Then you call select() with whatever timeout you want, passing the socket descriptor in both the read and write sets. If it doesn't timeout, it means the connect() call completed. At this point, you'll have to use getsockopt() with the SO_ERROR option to get the return value from the connect() call, which should be zero if there was no error.
Finally, you'll probably want to set the socket back to be blocking again before you start transferring data over it.
Notice that this has the added benefit of allowing your program to do something else while it's connecting, too. You could, for example, set the timeout to something low, like 500 ms, and update an indicator onscreen each timeout, then call select() again. When you've called select() and timed-out, say, 20 times, you'll know it's time to give up on the connection.
Like I said, check out Stevens' source for a perfectly excellent example.
First, delete Windows and install Linux or BSD. };-). No, actually, just see the section on building for Windows in the introduction.
The linker errors happen because Sun boxes don't automatically compile in the socket libraries. See the section on building for Solaris/SunOS in the introduction for an example of how to do this.
Signals tend to cause blocked system calls to return -1 with errno set to EINTR. When you set up a signal handler with sigaction(), you can set the flag SA_RESTART, which is supposed to restart the system call after it was interrupted.
Naturally, this doesn't always work.
My favorite solution to this involves a goto statement. You know this irritates your professors to no end, so go for it!
select_restart: if ((err = select(fdmax+1, &readfds, NULL, NULL, NULL)) == -1) { if (errno == EINTR) { // some signal just interrupted us, so restart goto select_restart; } // handle the real error here: perror("select"); }
Sure, you don't need to use goto in this case; you can use other structures to control it. But I think the goto statement is actually cleaner.
Use select()! It allows you to specify a timeout parameter for socket descriptors that you're looking to read from. Or, you could wrap the entire functionality in a single function, like this:
#include <unistd.h> #include <sys/time.h> #include <sys/types.h> #include <sys/socket.h> int recvtimeout(int s, char *buf, int len, int timeout) { fd_set fds; int n; struct timeval tv; // set up the file descriptor set FD_ZERO(&fds); FD_SET(s, &fds); // set up the struct timeval for the timeout tv.tv_sec = timeout; tv.tv_usec = 0; // wait until timeout or data received n = select(s+1, &fds, NULL, NULL, &tv); if (n == 0) return -2; // timeout! if (n == -1) return -1; // error // data must be here, so do a normal recv() return recv(s, buf, len, 0); } . . . // Sample call to recvtimeout(): n = recvtimeout(s, buf, sizeof buf, 10); // 10 second timeout if (n == -1) { // error occurred perror("recvtimeout"); } else if (n == -2) { // timeout occurred } else { // got some data in buf } . . .
Notice that recvtimeout() returns -2 in case of a timeout. Why not return 0? Well, if you recall, a return value of 0 on a call to recv() means that the remote side closed the connection. So that return value is already spoken for, and -1 means "error", so I chose -2 as my timeout indicator.
One easy way to do encryption is to use SSL (secure sockets layer), but that's beyond the scope of this guide. (Check out the OpenSSL project for more info.)
But assuming you want to plug in or implement your own compressor or encryption system, it's just a matter of thinking of your data as running through a sequence of steps between both ends. Each step changes the data in some way.
Now the other way around:
If you're going to compress and encrypt, just remember to compress first. :-)
Just as long as the client properly undoes what the server does, the data will be fine in the end no matter how many intermediate steps you add.
So all you need to do to use my code is to find the place between where the data is read and the data is sent (using send()) over the network, and stick some code in there that does the encryption.
Yes, yes it is. See the section on socket() for details.
For simplicity, lets say the client connect()s, send()s, and close()s the connection (that is, there are no subsequent system calls without the client connecting again.)
The process the client follows is this:
Meanwhile, the server is handling the data and executing it:
Beware! Having the server execute what the client says is like giving remote shell access and people can do things to your account when they connect to the server. For instance, in the above example, what if the client sends "rm -rf ~"? It deletes everything in your account, that's what!
So you get wise, and you prevent the client from using any except for a couple utilities that you know are safe, like the foobar utility:
if (!strncmp(str, "foobar", 6)) { sprintf(sysstr, "%s > /tmp/server.out", str); system(sysstr); }
But you're still unsafe, unfortunately: what if the client enters "foobar; rm -rf ~"? The safest thing to do is to write a little routine that puts an escape ("\") character in front of all non-alphanumeric characters (including spaces, if appropriate) in the arguments for the command.
As you can see, security is a pretty big issue when the server starts executing things the client sends.
You're hitting the MTU—the maximum size the physical medium can handle. On the local machine, you're using the loopback device which can handle 8K or more no problem. But on Ethernet, which can only handle 1500 bytes with a header, you hit that limit. Over a modem, with 576 MTU (again, with header), you hit the even lower limit.
You have to make sure all the data is being sent, first of all. (See the sendall() function implementation for details.) Once you're sure of that, then you need to call recv() in a loop until all your data is read.
Read the section Son of Data Encapsulation for details on receiving complete packets of data using multiple calls to recv().
If they're anywhere, they'll be in POSIX libraries
that may have shipped with your compiler. Since I don't have a Windows
box, I really can't tell you the answer, but I seem to remember that
Microsoft has a POSIX compatibility layer and that's where
fork() would be. (And maybe even
Search the help that came with VC++ for "fork" or "POSIX" and see if it gives you any clues.
If that doesn't work at all, ditch the
fork()/
Unfortunately, the purpose of a firewall is to prevent people outside the firewall from connecting to machines inside the firewall, so allowing them to do so is basically considered a breach of security.
This isn't to say that all is lost. For one thing, you can still often connect() through the firewall if it's doing some kind of masquerading or NAT or something like that. Just design your programs so that you're always the one initiating the connection, and you'll be fine.
If that's not satisfactory, you can ask your sysadmins to poke a hole in the firewall so that people can connect to you. The firewall can forward to you either through it's NAT software, or through a proxy or something like that.
Be aware that a hole in the firewall is nothing to be taken lightly. You have to make sure you don't give bad people access to the internal network; if you're a beginner, it's a lot harder to make software secure than you might imagine.
Don't make your sysadmin mad at me. ;-)
For those not in the know, when a network card is in "promiscuous mode", it will forward ALL packets to the operating system, not just those that were addressed to this particular machine. (We're talking Ethernet-layer addresses here, not IP addresses--but since ethernet is lower-layer than IP, all IP addresses are effectively forwarded as well. See the section Low Level Nonsense and Network Theory for more info.)
This is the basis for how a packet sniffer works. It puts the interface into promiscuous mode, then the OS gets every single packet that goes by on the wire. You'll have a socket of some type that you can read this data from.
Unfortunately, the answer to the question varies depending on the platform, but if you Google for, for instance, "windows promiscuous ioctl" you'll probably get somewhere. There's what looks like a decent writeup in Linux Journal, as well.
It depends on your system. You might search the net for SO_RCVTIMEO and SO_SNDTIMEO (for use with setsockopt()) to see if your system supports such functionality.
The Linux man page suggests using alarm() or setitimer() as a substitute.
Usually this isn't an issue. If you're writing, say, a web server, then it's a good idea to use the well-known port 80 for your software. If you're writing just your own specialized server, then choose a port at random (but greater than 1023) and give it a try.
If the port is already in use, you'll get an "Address already in use" error when you try to bind(). Choose another port. (It's a good idea to allow the user of your software to specify an alternate port either with a config file or a command line switch.)
There is a list of official port numbers maintained by the Internet Assigned Numbers Authority (IANA). Just because something (over 1023) is in that list doesn't mean you can't use the port. For instance, Id Software's DOOM uses the same port as "mdqs", whatever that is. All that matters is that no one else on the same machine is using that port when you want to use it.
In the Unix world, there are a lot of manuals. They have little sections that describe individual functions that you have at your disposal.
Of course, manual would be too much of a thing to type. I mean, no one in the Unix world, including myself, likes to type that much. Indeed I could go on and on at great length about how much I prefer to be terse but instead I shall be brief and not bore you with long-winded diatribes about how utterly amazingly brief I prefer to be in virtually all circumstances in their entirety.
[Applause]
Thank you. What I am getting at is that these pages are called "man pages" in the Unix world, and I have included my own personal truncated variant here for your reading enjoyment. The thing is, many of these functions are way more general purpose than I'm letting on, but I'm only going to present the parts that are relevant for Internet Sockets Programming.
But wait! That's not all that's wrong with my man pages:
If you want the real information, check your local Unix man pages by typing man whatever, where "whatever" is something that you're incredibly interested in, such as "accept". (I'm sure Microsoft Visual Studio has something similar in their help section. But "man" is better because it is one byte more concise than "help". Unix wins again!)
So, if these are so flawed, why even include them at all in the Guide? Well, there are a few reasons, but the best are that (a) these versions are geared specifically toward network programming and are easier to digest than the real ones, and (b) these versions contain examples!
Oh! And speaking of the examples, I don't tend to put in all the error checking because it really increases the length of the code. But you should absolutely do error checking pretty much any time you make any of the system calls unless you're totally 100% sure it's not going to fail, and you should probably do it even then!
Accept an incoming connection on a listening socket
#include <sys/types.h> #include <sys/socket.h> int accept(int s, struct sockaddr *addr, socklen_t *addrlen);
Once you've gone through the trouble of getting a SOCK_STREAM socket and setting it up for incoming connections with listen(), then you call accept() to actually get yourself a new socket descriptor to use for subsequent communication with the newly connected client.
The old socket that you are using for listening is still there, and will be used for further accept() calls as they come in.
accept() will normally block, and you can use select() to peek on the listening socket descriptor ahead of time to see if it's "ready to read". If so, then there's a new connection waiting to be accept()ed! Yay! Alternatively, you could set the O_NONBLOCK flag on the listening socket using fcntl(), and then it will never block, choosing instead to return -1 with errno set to EWOULDBLOCK.
The socket descriptor returned by accept() is a bona fide socket descriptor, open and connected to the remote host. You have to close() it when you're done with it.
accept() returns the newly connected socket descriptor, or -1 on error, with errno set appropriately.
struct sockaddr_storage their_addr; socklen_t addr_size; struct addrinfo hints, *res; int sockfd, new_fd; // first, load up address structs with getaddrinfo(): memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; // use IPv4 or IPv6, whichever hints.ai_socktype = SOCK_STREAM; hints.ai_flags = AI_PASSIVE; // fill in my IP for me getaddrinfo(NULL, MYPORT, &hints, &res); // make a socket, bind it, and listen on it: sockfd = socket(res->ai_family, res->ai_socktype, res->ai_protocol); bind(sockfd, res->ai_addr, res->ai_addrlen); listen(sockfd, BACKLOG); // now accept an incoming connection: addr_size = sizeof their_addr; new_fd = accept(sockfd, (struct sockaddr *)&their_addr, &addr_size); // ready to communicate on socket descriptor new_fd!
socket(),
getaddrinfo(),
listen(),
Associate a socket with an IP address and port number
#include <sys/types.h> #include <sys/socket.h> int bind(int sockfd, struct sockaddr *my_addr, socklen_t addrlen);
When a remote machine wants to connect to your server program, it needs two pieces of information: the IP address and the port number. The bind() call allows you to do just that.
First, you call getaddrinfo() to load up a struct sockaddr with the destination address and port information. Then you call socket() to get a socket descriptor, and then you pass the socket and address into bind(), and the IP address and port are magically (using actual magic) bound to the socket!
If you don't know your IP address, or you know you only have one IP address on the machine, or you don't care which of the machine's IP addresses is used, you can simply pass the AI_PASSIVE flag in the hints parameter to getaddrinfo(). What this does is fill in the IP address part of the struct sockaddr with a special value that tells bind() that it should automatically fill in this host's IP address.
What what? What special value is loaded into the struct
sockaddr's IP address to cause it to auto-fill the address with
the current host? I'll tell you, but keep in mind this is only if
you're filling out the
Lastly, the addrlen parameter should be set to sizeof my_addr.
Returns zero on success, or -1 on error (and errno will be set accordingly.)
// modern way of doing things with getaddrinfo() struct addrinfo hints, *res; int sockfd; // first, load up address structs with getaddrinfo(): memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; // use IPv4 or IPv6, whichever hints.ai_socktype = SOCK_STREAM; hints.ai_flags = AI_PASSIVE; // fill in my IP for me getaddrinfo(NULL, "3490", &hints, &res); // make a socket: // (you should actually walk the "res" linked list and error-check!) sockfd = socket(res->ai_family, res->ai_socktype, res->ai_protocol); // bind it to the port we passed in to getaddrinfo(): bind(sockfd, res->ai_addr, res->ai_addrlen);
// example of packing a struct by hand, IPv4 struct sockaddr_in myaddr; int s; myaddr.sin_family = AF_INET; myaddr.sin_port = htons(3490); // you can specify an IP address: inet_pton(AF_INET, "63.161.169.137", &(myaddr.sin_addr)); // or you can let it automatically select one: myaddr.sin_addr.s_addr = INADDR_ANY; s = socket(PF_INET, SOCK_STREAM, 0); bind(s, (struct sockaddr*)&myaddr, sizeof myaddr);
getaddrinfo(),
socket(),
Connect a socket to a server
#include <sys/types.h> #include <sys/socket.h> int connect(int sockfd, const struct sockaddr *serv_addr, socklen_t addrlen);
Once you've built a socket descriptor with the socket() call, you can connect() that socket to a remote server using the well-named connect() system call. All you need to do is pass it the socket descriptor and the address of the server you're interested in getting to know better. (Oh, and the length of the address, which is commonly passed to functions like this.)
Usually this information comes along as the result of a call to
getaddrinfo(), but you can fill out your own
If you haven't yet called bind() on the socket descriptor, it is automatically bound to your IP address and a random local port. This is usually just fine with you if you're not a server, since you really don't care what your local port is; you only care what the remote port is so you can put it in the serv_addr parameter. You can call bind() if you really want your client socket to be on a specific IP address and port, but this is pretty rare.
Once the socket is connect()ed, you're free to send() and recv() data on it to your heart's content.
Special note: if you connect() a SOCK_DGRAM UDP socket to a remote host, you can use send() and recv() as well as sendto() and recvfrom(). If you want.
Returns zero on success, or -1 on error (and errno will be set accordingly.)
// connect to www.example.com port 80 (http) struct addrinfo hints, *res; int sockfd; // first, load up address structs with getaddrinfo(): memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; // use IPv4 or IPv6, whichever hints.ai_socktype = SOCK_STREAM; // we could put "80" instead on "http" on the next line: getaddrinfo("www.example.com", "http", &hints, &res); // make a socket: sockfd = socket(res->ai_family, res->ai_socktype, res->ai_protocol); // connect it to the address and port we passed in to getaddrinfo(): connect(sockfd, res->ai_addr, res->ai_addrlen);
Close a socket descriptor
#include <unistd.h> int close(int s);
After you've finished using the socket for whatever demented scheme you have concocted and you don't want to send() or recv() or, indeed, do anything else at all with the socket, you can close() it, and it'll be freed up, never to be used again.
The remote side can tell if this happens one of two ways. One: if the remote side calls recv(), it will return 0. Two: if the remote side calls send(), it'll receive a signal SIGPIPE and send() will return -1 and errno will be set to EPIPE.
Windows users: the function you need to use is called closesocket(), not close(). If you try to use close() on a socket descriptor, it's possible Windows will get angry... And you wouldn't like it when it's angry.
Returns zero on success, or -1 on error (and errno will be set accordingly.)
s = socket(PF_INET, SOCK_DGRAM, 0); . . . // a whole lotta stuff...*BRRRONNNN!* . . . close(s); // not much to it, really.
Get information about a host name and/or service and load up a
#include <sys/types.h> #include <sys/socket.h> #include <netdb.h> int getaddrinfo(const char *nodename, const char *servname, const struct addrinfo *hints, struct addrinfo **res); void freeaddrinfo(struct addrinfo *ai); const char *gai_strerror(int ecode); struct addrinfo { int ai_flags; // AI_PASSIVE, AI_CANONNAME, ... int ai_family; // AF_xxx int ai_socktype; // SOCK_xxx int ai_protocol; // 0 (auto) or IPPROTO_TCP, IPPROTO_UDP socklen_t ai_addrlen; // length of ai_addr char *ai_canonname; // canonical name for nodename struct sockaddr *ai_addr; // binary address struct addrinfo *ai_next; // next structure in linked list };
getaddrinfo() is an excellent function that will return
information on a particular host name (such as its IP address) and load
up a
The host name that you're interested in goes in the nodename parameter. The address can be either a host name, like "www.example.com", or an IPv4 or IPv6 address (passed as a string). This parameter can also be NULL if you're using the AI_PASSIVE flag (see below.)
The servname parameter is basically the port number. It can be a port number (passed as a string, like "80"), or it can be a service name, like "http" or "tftp" or "smtp" or "pop", etc. Well-known service names can be found in the IANA Port List or in your /etc/services file.
Lastly, for input parameters, we have hints. This is really where you get to define what the getaddrinfo() function is going to do. Zero the whole structure before use with memset(). Let's take a look at the fields you need to set up before use.
The ai_flags can be set to a variety of things, but here are a couple important ones. (Multiple flags can be specified by bitwise-ORing them together with the | operator.) Check your man page for the complete list of flags.
AI_CANONNAME causes the ai_canonname
of the result to the filled out with the host's canonical (real) name.
AI_PASSIVE causes the result's IP address to
be filled out with INADDR_ANY (IPv4)or
in6addr_any (IPv6); this causes a subsequent call to
bind() to auto-fill the IP address of the
If you do use the AI_PASSIVE, flag, then you can pass NULL in the nodename (since bind() will fill it in for you later.)
Continuing on with the input paramters, you'll likely want to set ai_family to AF_UNSPEC which tells getaddrinfo() to look for both IPv4 and IPv6 addresses. You can also restrict yourself to one or the other with AF_INET or AF_INET6.
Next, the socktype field should be set to SOCK_STREAM or SOCK_DGRAM, depending on which type of socket you want.
Finally, just leave ai_protocol at 0 to automatically choose your protocol type.
Now, after you get all that stuff in there, you can finally make the call to getaddrinfo()!
Of course, this is where the fun begins. The res will
now point to a linked list of
Now, it's possible to get some addresses that don't work for one reason or another, so what the Linux man page does is loops through the list doing a call to socket() and connect() (or bind() if you're setting up a server with the AI_PASSIVE flag) until it succeeds.
Finally, when you're done with the linked list, you need to call freeaddrinfo() to free up the memory (or it will be leaked, and Some People will get upset.)
Returns zero on success, or nonzero on error. If it returns nonzero, you can use the function gai_strerror() to get a printable version of the error code in the return value.
// code for a client connecting to a server // namely a stream socket to www.example.com on port 80 (http) // either IPv4 or IPv6 int sockfd; struct addrinfo hints, *servinfo, *p; int rv; memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; // use AF_INET6 to force IPv6 hints.ai_socktype = SOCK_STREAM; if ((rv = getaddrinfo("www.example.com", "http", &hints, &servinfo)) != 0) { fprintf(stderr, "getaddrinfo: %s\n", gai_strerror(rv)); exit(1); } // loop through all the results and connect to the first we can for(p = servinfo; p != NULL; p = p->ai_next) { if ((sockfd = socket(p->ai_family, p->ai_socktype, p->ai_protocol)) == -1) { perror("socket"); continue; } if (connect(sockfd, p->ai_addr, p->ai_addrlen) == -1) { close(sockfd); perror("connect"); continue; } break; // if we get here, we must have connected successfully } if (p == NULL) { // looped off the end of the list with no connection fprintf(stderr, "failed to connect\n"); exit(2); } freeaddrinfo(servinfo); // all done with this structure
// code for a server waiting for connections // namely a stream socket on port 3490, on this host's IP // either IPv4 or IPv6. int sockfd; struct addrinfo hints, *servinfo, *p; int rv; memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; // use AF_INET6 to force IPv6 hints.ai_socktype = SOCK_STREAM; hints.ai_flags = AI_PASSIVE; // use my IP address if ((rv = getaddrinfo(NULL, "3490", &hints, &servinfo)) != 0) { fprintf(stderr, "getaddrinfo: %s\n", gai_strerror(rv)); exit(1); } // loop through all the results and bind to the first we can for(p = servinfo; p != NULL; p = p->ai_next) { if ((sockfd = socket(p->ai_family, p->ai_socktype, p->ai_protocol)) == -1) { perror("socket"); continue; } if (bind(sockfd, p->ai_addr, p->ai_addrlen) == -1) { close(sockfd); perror("bind"); continue; } break; // if we get here, we must have connected successfully } if (p == NULL) { // looped off the end of the list with no successful bind fprintf(stderr, "failed to bind socket\n"); exit(2); } freeaddrinfo(servinfo); // all done with this structure
gethostbyname(), getnameinfo()
Returns the name of the system
#include <sys/unistd.h> int gethostname(char *name, size_t len);
Your system has a name. They all do. This is a slightly more Unixy thing than the rest of the networky stuff we've been talking about, but it still has its uses.
For instance, you can get your host name, and then call gethostbyname() to find out your IP address.
The parameter name should point to a buffer that will hold the host name, and len is the size of that buffer in bytes. gethostname() won't overwrite the end of the buffer (it might return an error, or it might just stop writing), and it will NUL-terminate the string if there's room for it in the buffer.
Returns zero on success, or -1 on error (and errno will be set accordingly.)
char hostname[128]; gethostname(hostname, sizeof hostname); printf("My hostname: %s\n", hostname);
Get an IP address for a hostname, or vice-versa
#include <sys/socket.h> #include <netdb.h> struct hostent *gethostbyname(const char *name); // DEPRECATED! struct hostent *gethostbyaddr(const char *addr, int len, int type);
PLEASE NOTE: these two functions are superseded by getaddrinfo() and getnameinfo()! In particular, gethostbyname() doesn't work well with IPv6.
These functions map back and forth between host names and IP
addresses. For instance, if you have "www.example.com", you can use
gethostbyname() to get its IP address and store it in a
Conversely, if you have a
(If you have a string containing an IP address in dots-and-numbers format that you want to look up the hostname of, you'd be better off using getaddrinfo() with the AI_CANONNAME flag.)
gethostbyname() takes a string like "www.yahoo.com", and
returns a
gethostbyaddr() takes a
So what is this
char *h_name |
The real canonical host name. |
char **h_aliases |
A list of aliases that can be accessed with arrays—the last element is NULL |
int h_addrtype |
The result's address type, which really should be AF_INET for our purposes. |
int length |
The length of the addresses in bytes, which is 4 for IP (version 4) addresses. |
char **h_addr_list |
A list of IP addresses for this host. Although this
is a |
h_addr |
A commonly defined alias for h_addr_list[0]. If you just want any old IP address for this host (yeah, they can have more than one) just use this field. |
Returns a pointer to a resultant
Instead of the normal perror() and all that stuff you'd normally use for error reporting, these functions have parallel results in the variable h_errno, which can be printed using the functions herror() or hstrerror(). These work just like the classic errno, perror(), and strerror() functions you're used to.
// THIS IS A DEPRECATED METHOD OF GETTING HOST NAMES // use getaddrinfo() instead! #include <stdio.h> #include <errno.h> #include <netdb.h> #include <sys/types.h> #include <sys/socket.h> #include <netinet/in.h> #include <arpa/inet.h> int main(int argc, char *argv[]) { int i; struct hostent *he; struct in_addr **addr_list; if (argc != 2) { fprintf(stderr,"usage: ghbn hostname\n"); return 1; } if ((he = gethostbyname(argv[1])) == NULL) { // get the host info herror("gethostbyname"); return 2; } // print information about this host: printf("Official name is: %s\n", he->h_name); printf(" IP addresses: "); addr_list = (struct in_addr **)he->h_addr_list; for(i = 0; addr_list[i] != NULL; i++) { printf("%s ", inet_ntoa(*addr_list[i])); } printf("\n"); return 0; }
// THIS HAS BEEN SUPERCEDED // use getnameinfo() instead! struct hostent *he; struct in_addr ipv4addr; struct in6_addr ipv6addr; inet_pton(AF_INET, "192.0.2.34", &ipv4addr); he = gethostbyaddr(&ipv4addr, sizeof ipv4addr, AF_INET); printf("Host name: %s\n", he->h_name); inet_pton(AF_INET6, "2001:db8:63b3:1::beef", &ipv6addr); he = gethostbyaddr(&ipv6addr, sizeof ipv6addr, AF_INET6); printf("Host name: %s\n", he->h_name);
getaddrinfo(),
getnameinfo(),
gethostname(),
errno,
perror(),
strerror(),
Look up the host name and service name information for a given
#include <sys/socket.h> #include <netdb.h> int getnameinfo(const struct sockaddr *sa, socklen_t salen, char *host, size_t hostlen, char *serv, size_t servlen, int flags);
This function is the opposite of getaddrinfo(), that is,
this function takes an already loaded
You have to pass in a pointer to a
The resultant host name and service name will be written to the area pointed to by the host and serv parameters. Of course, you have to specify the max lengths of these buffers in hostlen and servlen.
Finally, there are several flags you can pass, but here a a couple good ones. NI_NOFQDN will cause the host to only contain the host name, not the whole domain name. NI_NAMEREQD will cause the function to fail if the name cannot be found with a DNS lookup (if you don't specify this flag and the name can't be found, getnameinfo() will put a string version of the IP address in host instead.)
As always, check your local man pages for the full scoop.
Returns zero on success, or non-zero on error. If the return value is non-zero, it can be passed to gai_strerror() to get a human-readable string. See getaddrinfo for more information.
struct sockaddr_in6 sa; // could be IPv4 if you want char host[1024]; char service[20]; // pretend sa is full of good information about the host and port... getnameinfo(&sa, sizeof sa, host, sizeof host, service, sizeof service, 0); printf(" host: %s\n", host); // e.g. "www.example.com" printf("service: %s\n", service); // e.g. "http"
getaddrinfo(), gethostbyaddr()
Return address info about the remote side of the connection
#include <sys/socket.h> int getpeername(int s, struct sockaddr *addr, socklen_t *len);
Once you have either accept()ed a remote connection, or connect()ed to a server, you now have what is known as a peer. Your peer is simply the computer you're connected to, identified by an IP address and a port. So...
getpeername() simply returns a
Why is it called a "name"? Well, there are a lot of different kinds of sockets, not just Internet Sockets like we're using in this guide, and so "name" was a nice generic term that covered all cases. In our case, though, the peer's "name" is it's IP address and port.
Although the function returns the size of the resultant address in len, you must preload len with the size of addr.
Returns zero on success, or -1 on error (and errno will be set accordingly.)
// assume s is a connected socket socklen_t len; struct sockaddr_storage addr; char ipstr[INET6_ADDRSTRLEN]; int port; len = sizeof addr; getpeername(s, (struct sockaddr*)&addr, &len); // deal with both IPv4 and IPv6: if (addr.ss_family == AF_INET) { struct sockaddr_in *s = (struct sockaddr_in *)&addr; port = ntohs(s->sin_port); inet_ntop(AF_INET, &s->sin_addr, ipstr, sizeof ipstr); } else { // AF_INET6 struct sockaddr_in6 *s = (struct sockaddr_in6 *)&addr; port = ntohs(s->sin6_port); inet_ntop(AF_INET6, &s->sin6_addr, ipstr, sizeof ipstr); } printf("Peer IP address: %s\n", ipstr); printf("Peer port : %d\n", port);
gethostname(), gethostbyname(), gethostbyaddr()
Holds the error code for the last system call
#include <errno.h> int errno;
This is the variable that holds error information for a lot of system calls. If you'll recall, things like socket() and listen() return -1 on error, and they set the exact value of errno to let you know specifically which error occurred.
The header file errno.h lists a bunch of constant symbolic names for errors, such as EADDRINUSE, EPIPE, ECONNREFUSED, etc. Your local man pages will tell you what codes can be returned as an error, and you can use these at run time to handle different errors in different ways.
Or, more commonly, you can call perror() or strerror() to get a human-readable version of the error.
One thing to note, for you multithreading enthusiasts, is that on most systems errno is defined in a threadsafe manner. (That is, it's not actually a global variable, but it behaves just like a global variable would in a single-threaded environment.)
The value of the variable is the latest error to have transpired, which might be the code for "success" if the last action succeeded.
s = socket(PF_INET, SOCK_STREAM, 0); if (s == -1) { perror("socket"); // or use strerror() } tryagain: if (select(n, &readfds, NULL, NULL) == -1) { // an error has occurred!! // if we were only interrupted, just restart the select() call: if (errno == EINTR) goto tryagain; // AAAA! goto!!! // otherwise it's a more serious error: perror("select"); exit(1); }
Control socket descriptors
#include <sys/unistd.h> #include <sys/fcntl.h> int fcntl(int s, int cmd, long arg);
This function is typically used to do file locking and other file-oriented stuff, but it also has a couple socket-related functions that you might see or use from time to time.
Parameter s is the socket descriptor you wish to operate on, cmd should be set to F_SETFL, and arg can be one of the following commands. (Like I said, there's more to fcntl() than I'm letting on here, but I'm trying to stay socket-oriented.)
Set the socket to be non-blocking. See the section on blocking for more details. |
|
Set the socket to do asynchronous I/O. When data is ready to be recv()'d on the socket, the signal SIGIO will be raised. This is rare to see, and beyond the scope of the guide. And I think it's only available on certain systems. |
Returns zero on success, or -1 on error (and errno will be set accordingly.)
Different uses of the fcntl() system call actually have different return values, but I haven't covered them here because they're not socket-related. See your local fcntl() man page for more information.
int s = socket(PF_INET, SOCK_STREAM, 0); fcntl(s, F_SETFL, O_NONBLOCK); // set to non-blocking fcntl(s, F_SETFL, O_ASYNC); // set to asynchronous I/O
Convert multi-byte integer types from host byte order to network byte order
#include <netinet/in.h> uint32_t htonl(uint32_t hostlong); uint16_t htons(uint16_t hostshort); uint32_t ntohl(uint32_t netlong); uint16_t ntohs(uint16_t netshort);
Just to make you really unhappy, different computers use
different byte orderings internally for their multibyte integers (i.e.
any integer that's larger than a
The way to get around this problem is for everyone to put aside their differences and agree that Motorola and IBM had it right, and Intel did it the weird way, and so we all convert our byte orderings to "big-endian" before sending them out. Since Intel is a "little-endian" machine, it's far more politically correct to call our preferred byte ordering "Network Byte Order". So these functions convert from your native byte order to network byte order and back again.
(This means on Intel these functions swap all the bytes around, and on PowerPC they do nothing because the bytes are already in Network Byte Order. But you should always use them in your code anyway, since someone might want to build it on an Intel machine and still have things work properly.)
Note that the types involved are 32-bit (4 byte, probably
Anyway, the way these functions work is that you first decide if you're converting from host (your machine's) byte order or from network byte order. If "host", the the first letter of the function you're going to call is "h". Otherwise it's "n" for "network". The middle of the function name is always "to" because you're converting from one "to" another, and the penultimate letter shows what you're converting to. The last letter is the size of the data, "s" for short, or "l" for long. Thus:
host to network short |
|
host to network long |
|
network to host short |
|
network to host long |
Each function returns the converted value.
uint32_t some_long = 10; uint16_t some_short = 20; uint32_t network_byte_order; // convert and send network_byte_order = htonl(some_long); send(s, &network_byte_order, sizeof(uint32_t), 0); some_short == ntohs(htons(some_short)); // this expression is true
Convert IP addresses from a dots-and-number string to a
#include <sys/socket.h> #include <netinet/in.h> #include <arpa/inet.h> // ALL THESE ARE DEPRECATED! Use inet_pton() or inet_ntop() instead!! char *inet_ntoa(struct in_addr in); int inet_aton(const char *cp, struct in_addr *inp); in_addr_t inet_addr(const char *cp);
These functions are deprecated because they don't handle IPv6! Use inet_ntop() or inet_pton() instead! They are included here because they can still be found in the wild.
All of these functions convert from a
The function inet_ntoa() converts a network address in a
The function inet_aton() is the opposite, converting
from a dots-and-numbers string into a
Finally, the function inet_addr() is an older function that does basically the same thing as inet_aton(). It's theoretically deprecated, but you'll see it a lot and the police won't come get you if you use it.
inet_aton() returns non-zero if the address is a valid one, and it returns zero if the address is invalid.
inet_ntoa() returns the dots-and-numbers string in a static buffer that is overwritten with each call to the function.
inet_addr() returns the address as an
struct sockaddr_in antelope; char *some_addr; inet_aton("10.0.0.1", &antelope.sin_addr); // store IP in antelope some_addr = inet_ntoa(antelope.sin_addr); // return the IP printf("%s\n", some_addr); // prints "10.0.0.1" // and this call is the same as the inet_aton() call, above: antelope.sin_addr.s_addr = inet_addr("10.0.0.1");
inet_ntop(), inet_pton(), gethostbyname(), gethostbyaddr()
Convert IP addresses to human-readable form and back.
#include <arpa/inet.h> const char *inet_ntop(int af, const void *src, char *dst, socklen_t size); int inet_pton(int af, const char *src, void *dst);
These functions are for dealing with human-readable IP addresses and converting them to their binary representation for use with various functions and system calls. The "n" stands for "network", and "p" for "presentation". Or "text presentation". But you can think of it as "printable". "ntop" is "network to printable". See?
Sometimes you don't want to look at a pile of binary numbers when looking at an IP address. You want it in a nice printable form, like 192.0.2.180, or 2001:db8:8714:3a90::12. In that case, inet_ntop() is for you.
inet_ntop() takes the address family in the
af parameter (either AF_INET or
AF_INET6). The src parameter should be a
pointer to either a
What should the maximum length of the dst string be? What is the maximum length for IPv4 and IPv6 addresses? Fortunately there are a couple of macros to help you out. The maximum lengths are: INET_ADDRSTRLEN and INET6_ADDRSTRLEN.
Other times, you might have a string containing an IP address in
readable form, and you want to pack it into a
inet_pton() also takes an address family (either
AF_INET or AF_INET6) in the
af parameter. The src parameter is a
pointer to a string containing the IP address in printable form. Lastly
the dst parameter points to where the result should be
stored, which is probably a
These functions don't do DNS lookups—you'll need getaddrinfo() for that.
inet_ntop() returns the dst parameter on success, or NULL on failure (and errno is set).
inet_pton() returns 1 on success. It returns -1 if there was an error (errno is set), or 0 if the input isn't a valid IP address.
// IPv4 demo of inet_ntop() and inet_pton() struct sockaddr_in sa; char str[INET_ADDRSTRLEN]; // store this IP address in sa: inet_pton(AF_INET, "192.0.2.33", &(sa.sin_addr)); // now get it back and print it inet_ntop(AF_INET, &(sa.sin_addr), str, INET_ADDRSTRLEN); printf("%s\n", str); // prints "192.0.2.33"
// IPv6 demo of inet_ntop() and inet_pton() // (basically the same except with a bunch of 6s thrown around) struct sockaddr_in6 sa; char str[INET6_ADDRSTRLEN]; // store this IP address in sa: inet_pton(AF_INET6, "2001:db8:8714:3a90::12", &(sa.sin6_addr)); // now get it back and print it inet_ntop(AF_INET6, &(sa.sin6_addr), str, INET6_ADDRSTRLEN); printf("%s\n", str); // prints "2001:db8:8714:3a90::12"
// Helper function you can use: //Convert a struct sockaddr address to a string, IPv4 and IPv6: char *get_ip_str(const struct sockaddr *sa, char *s, size_t maxlen) { switch(sa->sa_family) { case AF_INET: inet_ntop(AF_INET, &(((struct sockaddr_in *)sa)->sin_addr), s, maxlen); break; case AF_INET6: inet_ntop(AF_INET6, &(((struct sockaddr_in6 *)sa)->sin6_addr), s, maxlen); break; default: strncpy(s, "Unknown AF", maxlen); return NULL; } return s; }
Tell a socket to listen for incoming connections
#include <sys/socket.h> int listen(int s, int backlog);
You can take your socket descriptor (made with the socket() system call) and tell it to listen for incoming connections. This is what differentiates the servers from the clients, guys.
The backlog parameter can mean a couple different things depending on the system you on, but loosely it is how many pending connections you can have before the kernel starts rejecting new ones. So as the new connections come in, you should be quick to accept() them so that the backlog doesn't fill. Try setting it to 10 or so, and if your clients start getting "Connection refused" under heavy load, set it higher.
Before calling listen(), your server should call bind() to attach itself to a specific port number. That port number (on the server's IP address) will be the one that clients connect to.
Returns zero on success, or -1 on error (and errno will be set accordingly.)
struct addrinfo hints, *res; int sockfd; // first, load up address structs with getaddrinfo(): memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; // use IPv4 or IPv6, whichever hints.ai_socktype = SOCK_STREAM; hints.ai_flags = AI_PASSIVE; // fill in my IP for me getaddrinfo(NULL, "3490", &hints, &res); // make a socket: sockfd = socket(res->ai_family, res->ai_socktype, res->ai_protocol); // bind it to the port we passed in to getaddrinfo(): bind(sockfd, res->ai_addr, res->ai_addrlen); listen(sockfd, 10); // set s up to be a server (listening) socket // then have an accept() loop down here somewhere
Print an error as a human-readable string
#include <stdio.h> #include <string.h> // for strerror() void perror(const char *s); char *strerror(int errnum);
Since so many functions return -1 on error and set the value of the variable errno to be some number, it would sure be nice if you could easily print that in a form that made sense to you.
Mercifully, perror() does that. If you want more description to be printed before the error, you can point the parameter s to it (or you can leave s as NULL and nothing additional will be printed.)
In a nutshell, this function takes errno values, like ECONNRESET, and prints them nicely, like "Connection reset by peer."
The function strerror() is very similar to perror(), except it returns a pointer to the error message string for a given value (you usually pass in the variable errno.)
strerror() returns a pointer to the error message string.
int s; s = socket(PF_INET, SOCK_STREAM, 0); if (s == -1) { // some error has occurred // prints "socket error: " + the error message: perror("socket error"); } // similarly: if (listen(s, 10) == -1) { // this prints "an error: " + the error message from errno: printf("an error: %s\n", strerror(errno)); }
Test for events on multiple sockets simultaneously
#include <sys/poll.h> int poll(struct pollfd *ufds, unsigned int nfds, int timeout);
This function is very similar to select() in that they both watch sets of file descriptors for events, such as incoming data ready to recv(), socket ready to send() data to, out-of-band data ready to recv(), errors, etc.
The basic idea is that you pass an array of nfds
Each element in the array of
struct pollfd { int fd; // the socket descriptor short events; // bitmap of events we're interested in short revents; // when poll() returns, bitmap of events that occurred };
Before calling poll(), load fd with the
socket descriptor (if you set fd to a negative number, this
POLLIN |
Alert me when data is ready to recv() on this socket. |
POLLOUT |
Alert me when I can send() data to this socket without blocking. |
POLLPRI |
Alert me when out-of-band data is ready to recv() on this socket. |
Once the poll() call returns, the revents field will be constructed as a bitwise-OR of the above fields, telling you which descriptors actually have had that event occur. Additionally, these other fields might be present:
POLLERR |
An error has occurred on this socket. |
POLLHUP |
The remote side of the connection hung up. |
POLLNVAL |
Something was wrong with the socket descriptor fd—maybe it's uninitialized? |
Returns the number of elements in the ufds array that have had event occur on them; this can be zero if the timeout occurred. Also returns -1 on error (and errno will be set accordingly.)
int s1, s2; int rv; char buf1[256], buf2[256]; struct pollfd ufds[2]; s1 = socket(PF_INET, SOCK_STREAM, 0); s2 = socket(PF_INET, SOCK_STREAM, 0); // pretend we've connected both to a server at this point //connect(s1, ...)... //connect(s2, ...)... // set up the array of file descriptors. // // in this example, we want to know when there's normal or out-of-band // data ready to be recv()'d... ufds[0].fd = s1; ufds[0].events = POLLIN | POLLPRI; // check for normal or out-of-band ufds[1] = s2; ufds[1].events = POLLIN; // check for just normal data // wait for events on the sockets, 3.5 second timeout rv = poll(ufds, 2, 3500); if (rv == -1) { perror("poll"); // error occurred in poll() } else if (rv == 0) { printf("Timeout occurred! No data after 3.5 seconds.\n"); } else { // check for events on s1: if (ufds[0].revents & POLLIN) { recv(s1, buf1, sizeof buf1, 0); // receive normal data } if (ufds[0].revents & POLLPRI) { recv(s1, buf1, sizeof buf1, MSG_OOB); // out-of-band data } // check for events on s2: if (ufds[1].revents & POLLIN) { recv(s1, buf2, sizeof buf2, 0); } }
Receive data on a socket
#include <sys/types.h> #include <sys/socket.h> ssize_t recv(int s, void *buf, size_t len, int flags); ssize_t recvfrom(int s, void *buf, size_t len, int flags, struct sockaddr *from, socklen_t *fromlen);
Once you have a socket up and connected, you can read incoming data from the remote side using the recv() (for TCP SOCK_STREAM sockets) and recvfrom() (for UDP SOCK_DGRAM sockets).
Both functions take the socket descriptor s, a pointer to the buffer buf, the size (in bytes) of the buffer len, and a set of flags that control how the functions work.
Additionally, the recvfrom() takes a
So what wondrous flags can you pass into this function? Here are some of them, but you should check your local man pages for more information and what is actually supported on your system. You bitwise-or these together, or just set flags to 0 if you want it to be a regular vanilla recv().
When you call recv(), it will block until there is some data to read. If you want to not block, set the socket to non-blocking or check with select() or poll() to see if there is incoming data before calling recv() or recvfrom().
Returns the number of bytes actually received (which might be less than you requested in the len parameter), or -1 on error (and errno will be set accordingly.)
If the remote side has closed the connection, recv() will return 0. This is the normal method for determining if the remote side has closed the connection. Normality is good, rebel!
// stream sockets and recv() struct addrinfo hints, *res; int sockfd; char buf[512]; int byte_count; // get host info, make socket, and connect it memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; // use IPv4 or IPv6, whichever hints.ai_socktype = SOCK_STREAM; getaddrinfo("www.example.com", "3490", &hints, &res); sockfd = socket(res->ai_family, res->ai_socktype, res->ai_protocol); connect(sockfd, res->ai_addr, res->ai_addrlen); // all right! now that we're connected, we can receive some data! byte_count = recv(sockfd, buf, sizeof buf, 0); printf("recv()'d %d bytes of data in buf\n", byte_count);
// datagram sockets and recvfrom() struct addrinfo hints, *res; int sockfd; int byte_count; socklen_t fromlen; struct sockaddr_storage addr; char buf[512]; char ipstr[INET6_ADDRSTRLEN]; // get host info, make socket, bind it to port 4950 memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; // use IPv4 or IPv6, whichever hints.ai_socktype = SOCK_DGRAM; hints.ai_flags = AI_PASSIVE; getaddrinfo(NULL, "4950", &hints, &res); sockfd = socket(res->ai_family, res->ai_socktype, res->ai_protocol); bind(sockfd, res->ai_addr, res->ai_addrlen); // no need to accept(), just recvfrom(): fromlen = sizeof addr; byte_count = recvfrom(sockfd, buf, sizeof buf, 0, &addr, &fromlen); printf("recv()'d %d bytes of data in buf\n", byte_count); printf("from IP address %s\n", inet_ntop(addr.ss_family, addr.ss_family == AF_INET? ((struct sockadd_in *)&addr)->sin_addr: ((struct sockadd_in6 *)&addr)->sin6_addr, ipstr, sizeof ipstr);
send(), sendto(), select(), poll(), Blocking
Check if sockets descriptors are ready to read/write
#include <sys/select.h> int select(int n, fd_set *readfds, fd_set *writefds, fd_set *exceptfds, struct timeval *timeout); FD_SET(int fd, fd_set *set); FD_CLR(int fd, fd_set *set); FD_ISSET(int fd, fd_set *set); FD_ZERO(fd_set *set);
The select() function gives you a way to simultaneously check multiple sockets to see if they have data waiting to be recv()d, or if you can send() data to them without blocking, or if some exception has occurred.
You populate your sets of socket descriptors using the macros, like FD_SET(), above. Once you have the set, you pass it into the function as one of the following parameters: readfds if you want to know when any of the sockets in the set is ready to recv() data, writefds if any of the sockets is ready to send() data to, and/or exceptfds if you need to know when an exception (error) occurs on any of the sockets. Any or all of these parameters can be NULL if you're not interested in those types of events. After select() returns, the values in the sets will be changed to show which are ready for reading or writing, and which have exceptions.
The first parameter, n is the highest-numbered socket
descriptor (they're just
Lastly, the
The helper macros do the following:
Add fd to the set. |
|
Remove fd from the set. |
|
Return true if fd is in the set. |
|
Clear all entries from the set. |
Returns the number of descriptors in the set on success, 0 if the timeout was reached, or -1 on error (and errno will be set accordingly.) Also, the sets are modified to show which sockets are ready.
int s1, s2, n; fd_set readfds; struct timeval tv; char buf1[256], buf2[256]; // pretend we've connected both to a server at this point //s1 = socket(...); //s2 = socket(...); //connect(s1, ...)... //connect(s2, ...)... // clear the set ahead of time FD_ZERO(&readfds); // add our descriptors to the set FD_SET(s1, &readfds); FD_SET(s2, &readfds); // since we got s2 second, it's the "greater", so we use that for // the n param in select() n = s2 + 1; // wait until either socket has data ready to be recv()d (timeout 10.5 secs) tv.tv_sec = 10; tv.tv_usec = 500000; rv = select(n, &readfds, NULL, NULL, &tv); if (rv == -1) { perror("select"); // error occurred in select() } else if (rv == 0) { printf("Timeout occurred! No data after 10.5 seconds.\n"); } else { // one or both of the descriptors have data if (FD_ISSET(s1, &readfds)) { recv(s1, buf1, sizeof buf1, 0); } if (FD_ISSET(s2, &readfds)) { recv(s2, buf2, sizeof buf2, 0); } }
Set various options for a socket
#include <sys/types.h> #include <sys/socket.h> int getsockopt(int s, int level, int optname, void *optval, socklen_t *optlen); int setsockopt(int s, int level, int optname, const void *optval, socklen_t optlen);
Sockets are fairly configurable beasts. In fact, they are so configurable, I'm not even going to cover it all here. It's probably system-dependent anyway. But I will talk about the basics.
Obviously, these functions get and set certain options on a socket. On a Linux box, all the socket information is in the man page for socket in section 7. (Type: "man 7 socket" to get all these goodies.)
As for parameters, s is the socket you're talking about, level should be set to SOL_SOCKET. Then you set the optname to the name you're interested in. Again, see your man page for all the options, but here are some of the most fun ones:
As for the parameter optval, it's usually a pointer to an
The final parameter, optlen, should be set to the length
of optval, probably sizeof(int), but varies
depending on the option. Note that in the case of
getsockopt(), this is a pointer to a
Warning: on some systems (notably Sun and Windows), the option
can be a
Returns zero on success, or -1 on error (and errno will be set accordingly.)
int optval; int optlen; char *optval2; // set SO_REUSEADDR on a socket to true (1): optval = 1; setsockopt(s1, SOL_SOCKET, SO_REUSEADDR, &optval, sizeof optval); // bind a socket to a device name (might not work on all systems): optval2 = "eth1"; // 4 bytes long, so 4, below: setsockopt(s2, SOL_SOCKET, SO_BINDTODEVICE, optval2, 4); // see if the SO_BROADCAST flag is set: getsockopt(s3, SOL_SOCKET, SO_BROADCAST, &optval, &optlen); if (optval != 0) { print("SO_BROADCAST enabled on s3!\n"); }
Send data out over a socket
#include <sys/types.h> #include <sys/socket.h> ssize_t send(int s, const void *buf, size_t len, int flags); ssize_t sendto(int s, const void *buf, size_t len, int flags, const struct sockaddr *to, socklen_t tolen);
These functions send data to a socket. Generally speaking, send() is used for TCP SOCK_STREAM connected sockets, and sendto() is used for UDP SOCK_DGRAM unconnected datagram sockets. With the unconnected sockets, you must specify the destination of a packet each time you send one, and that's why the last parameters of sendto() define where the packet is going.
With both send() and sendto(), the parameter s is the socket, buf is a pointer to the data you want to send, len is the number of bytes you want to send, and flags allows you to specify more information about how the data is to be sent. Set flags to zero if you want it to be "normal" data. Here are some of the commonly used flags, but check your local send() man pages for more details:
Send as "out of band" data. TCP supports this, and it's a way to tell the receiving system that this data has a higher priority than the normal data. The receiver will receive the signal SIGURG and it can then receive this data without first receiving all the rest of the normal data in the queue. |
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Don't send this data over a router, just keep it local. |
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If send() would block because outbound traffic is clogged, have it return EAGAIN. This is like a "enable non-blocking just for this send." See the section on blocking for more details. |
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If you send() to a remote host which is no longer recv()ing, you'll typically get the signal SIGPIPE. Adding this flag prevents that signal from being raised. |
Returns the number of bytes actually sent, or -1 on error (and errno will be set accordingly.) Note that the number of bytes actually sent might be less than the number you asked it to send! See the section on handling partial send()s for a helper function to get around this.
Also, if the socket has been closed by either side, the process calling send() will get the signal SIGPIPE. (Unless send() was called with the MSG_NOSIGNAL flag.)
int spatula_count = 3490; char *secret_message = "The Cheese is in The Toaster"; int stream_socket, dgram_socket; struct sockaddr_in dest; int temp; // first with TCP stream sockets: // assume sockets are made and connected //stream_socket = socket(... //connect(stream_socket, ... // convert to network byte order temp = htonl(spatula_count); // send data normally: send(stream_socket, &temp, sizeof temp, 0); // send secret message out of band: send(stream_socket, secret_message, strlen(secret_message)+1, MSG_OOB); // now with UDP datagram sockets: //getaddrinfo(... //dest = ... // assume "dest" holds the address of the destination //dgram_socket = socket(... // send secret message normally: sendto(dgram_socket, secret_message, strlen(secret_message)+1, 0, (struct sockaddr*)&dest, sizeof dest);
Stop further sends and receives on a socket
#include <sys/socket.h> int shutdown(int s, int how);
That's it! I've had it! No more send()s are allowed on this socket, but I still want to recv() data on it! Or vice-versa! How can I do this?
When you close() a socket descriptor, it closes both sides of the socket for reading and writing, and frees the socket descriptor. If you just want to close one side or the other, you can use this shutdown() call.
As for parameters, s is obviously the socket you want to perform this action on, and what action that is can be specified with the how parameter. How can be SHUT_RD to prevent further recv()s, SHUT_WR to prohibit further send()s, or SHUT_RDWR to do both.
Note that shutdown() doesn't free up the socket descriptor, so you still have to eventually close() the socket even if it has been fully shut down.
This is a rarely used system call.
Returns zero on success, or -1 on error (and errno will be set accordingly.)
int s = socket(PF_INET, SOCK_STREAM, 0); // ...do some send()s and stuff in here... // and now that we're done, don't allow any more sends()s: shutdown(s, SHUT_WR);
Allocate a socket descriptor
#include <sys/types.h> #include <sys/socket.h> int socket(int domain, int type, int protocol);
Returns a new socket descriptor that you can use to do sockety things with. This is generally the first call in the whopping process of writing a socket program, and you can use the result for subsequent calls to listen(), bind(), accept(), or a variety of other functions.
In usual usage, you get the values for these parameters from a call to getaddrinfo(), as shown in the example below. But you can fill them in by hand if you really want to.
The new socket descriptor to be used in subsequent calls, or -1 on error (and errno will be set accordingly.)
struct addrinfo hints, *res; int sockfd; // first, load up address structs with getaddrinfo(): memset(&hints, 0, sizeof hints); hints.ai_family = AF_UNSPEC; // AF_INET, AF_INET6, or AF_UNSPEC hints.ai_socktype = SOCK_STREAM; // SOCK_STREAM or SOCK_DGRAM getaddrinfo("www.example.com", "3490", &hints, &res); // make a socket using the information gleaned from getaddrinfo(): sockfd = socket(res->ai_family, res->ai_socktype, res->ai_protocol);
accept(), bind(), getaddrinfo(), listen()
Structures for handling internet addresses
#include <netinet/in.h> // All pointers to socket address structures are often cast to pointers // to this type before use in various functions and system calls: struct sockaddr { unsigned short sa_family; // address family, AF_xxx char sa_data[14]; // 14 bytes of protocol address }; // IPv4 AF_INET sockets: struct sockaddr_in { short sin_family; // e.g. AF_INET, AF_INET6 unsigned short sin_port; // e.g. htons(3490) struct in_addr sin_addr; // see struct in_addr, below char sin_zero[8]; // zero this if you want to }; struct in_addr { unsigned long s_addr; // load with inet_pton() }; // IPv6 AF_INET6 sockets: struct sockaddr_in6 { u_int16_t sin6_family; // address family, AF_INET6 u_int16_t sin6_port; // port number, Network Byte Order u_int32_t sin6_flowinfo; // IPv6 flow information struct in6_addr sin6_addr; // IPv6 address u_int32_t sin6_scope_id; // Scope ID }; struct in6_addr { unsigned char s6_addr[16]; // load with inet_pton() }; // General socket address holding structure, big enough to hold either // struct sockaddr_in or struct sockaddr_in6 data: struct sockaddr_storage { sa_family_t ss_family; // address family // all this is padding, implementation specific, ignore it: char __ss_pad1[_SS_PAD1SIZE]; int64_t __ss_align; char __ss_pad2[_SS_PAD2SIZE]; };
These are the basic structures for all syscalls and functions that deal with internet addresses. Often you'll use getaddrinfo() to fill these structures out, and then will read them when you have to.
In memory, the
Just kidding on that end-of-the-universe thing...if the universe does
end when you cast a
So, with that in mind, remember that whenever a function says it
takes a
There's also this
Now, that
// IPv4: struct sockaddr_in ip4addr; int s; ip4addr.sin_family = AF_INET; ip4addr.sin_port = htons(3490); inet_pton(AF_INET, "10.0.0.1", &ip4addr.sin_addr); s = socket(PF_INET, SOCK_STREAM, 0); bind(s, (struct sockaddr*)&ip4addr, sizeof ip4addr);
// IPv6: struct sockaddr_in6 ip6addr; int s; ip6addr.sin6_family = AF_INET6; ip6addr.sin6_port = htons(4950); inet_pton(AF_INET6, "2001:db8:8714:3a90::12", &ip6addr.sin6_addr); s = socket(PF_INET6, SOCK_STREAM, 0); bind(s, (struct sockaddr*)&ip6addr, sizeof ip6addr);
accept(), bind(), connect(), inet_aton(), inet_ntoa()
You've come this far, and now you're screaming for more! Where else can you go to learn more about all this stuff?
For old-school actual hold-it-in-your-hand pulp paper books, try some of the following excellent books. I used to be an affiliate with a very popular internet bookseller, but their new customer tracking system is incompatible with a print document. As such, I get no more kickbacks. If you feel compassion for my plight, paypal a donation to beej@beej.us. :-)
Unix Network Programming, volumes 1-2 by W. Richard Stevens. Published by Prentice Hall. ISBNs for volumes 1-2: 0131411551, 0130810819.
Internetworking with TCP/IP, volumes I-III by Douglas E. Comer and David L. Stevens. Published by Prentice Hall. ISBNs for volumes I, II, and III: 0131876716, 0130319961, 0130320714.
TCP/IP Illustrated, volumes 1-3 by W. Richard Stevens and Gary R. Wright. Published by Addison Wesley. ISBNs for volumes 1, 2, and 3 (and a 3-volume set): 0201633469, 020163354X, 0201634953, (0201776316).
TCP/IP Network Administration by Craig Hunt. Published by O'Reilly & Associates, Inc. ISBN 0596002971.
Advanced Programming in the UNIX Environment by W. Richard Stevens. Published by Addison Wesley. ISBN 0201433079.
BSD Sockets: A Quick And Dirty Primer (Unix system programming info, too!)
And here are some relevant Wikipedia pages:
Transmission Control Protocol (TCP)
Serialization (packing and unpacking data)
RFCs—the real dirt! These are documents that describe assigned numbers, programming APIs, and protocols that are used on the Internet. I've included links to a few of them here for your enjoyment, so grab a bucket of popcorn and put on your thinking cap:
RFC 1—The First RFC; this gives you an idea of what the "Internet" was like just as it was coming to life, and an insight into how it was being designed from the ground up. (This RFC is completely obsolete, obviously!)
RFC 768—The User Datagram Protocol (UDP)
RFC 791—The Internet Protocol (IP)
RFC 793—The Transmission Control Protocol (TCP)
RFC 854—The Telnet Protocol
RFC 959—File Transfer Protocol (FTP)
RFC 1350—The Trivial File Transfer Protocol (TFTP)
RFC 1459—Internet Relay Chat Protocol (IRC)
RFC 1918—Address Allocation for Private Internets
RFC 2131—Dynamic Host Configuration Protocol (DHCP)
RFC 2616—Hypertext Transfer Protocol (HTTP)
RFC 2821—Simple Mail Transfer Protocol (SMTP)
RFC 3330—Special-Use IPv4 Addresses
RFC 3493—Basic Socket Interface Extensions for IPv6
RFC 3542—Advanced Sockets Application Program Interface (API) for IPv6
RFC 3849—IPv6 Address Prefix Reserved for Documentation
RFC 3920—Extensible Messaging and Presence Protocol (XMPP)
RFC 3977—Network News Transfer Protocol (NNTP)
RFC 4193—Unique Local IPv6 Unicast Addresses
RFC 4506—External Data Representation Standard (XDR)
The IETF has a nice online tool for searching and browsing RFCs.
accept(): 5.5, 5.6, 9.1
Address already in use: 5.3, 8.0
AF_INET: 3.3, 5.2, 8.0
AF_INET6: 3.3
asynchronous I/O: 9.11
Bapper: 7.6
bind(): 5.3, 8.0, 9.2
implicit: 5.3, 5.4
blah blah blah: 2.2
blocking: 7.1
books: 10.1
broadcast: 7.6
byte ordering: 3.2, 3.3, 7.4, 9.12
client:
datagram: 6.3
stream: 6.2
client/server: 6.0
close(): 5.9, 9.4
closesocket(): 1.5, 5.9, 9.4
compilers:
gcc: 1.2
compression: 8.0
connect(): 2.1, 5.3, 5.3, 5.4, 9.3
on datagram sockets: 5.8, 6.3, 9.3
Connection refused: 6.2
CreateProcess(): 1.5, 8.0
CreateThread(): 1.5
Cygwin: 1.5
data encapsulation: 2.2, 7.3
DHCP: 10.3
disconnected network: see private network.
DNS:
domain name service: see DNS.
donkeys: 7.3
EAGAIN: 7.1, 7.1, 9.21
email to Beej: 1.6
encryption: 8.0
EPIPE: 9.4
errno: 9.10, 9.16
Ethernet: 2.2
EWOULDBLOCK: 7.1, 7.1, 9.1
Excalibur: 7.5
external data representation standard: see XDR.
F_SETFL: 9.11
fcntl(): 7.1, 9.1, 9.11
FD_CLR(): 7.2, 9.19
FD_ISSET(): 7.2, 9.19
FD_SET(): 7.2, 9.19
FD_ZERO(): 7.2, 9.19
file descriptor: 2.0
firewall: 3.4.1, 7.6, 8.0
poking holes in: 8.0
footer: 2.2
fork(): 1.5, 6.0, 8.0
FTP: 10.3
getaddrinfo(): 3.3, 4.0, 5.1
gethostbyaddr(): 5.10, 9.7
gethostbyname(): 5.11, 9.6, 9.7
gethostname(): 5.11, 9.6
getnameinfo(): 4.0, 5.10
getpeername(): 5.10, 9.9
getprotobyname(): 9.23
getsockopt(): 9.20
gettimeofday(): 7.2
goat: 8.0
goto: 8.0
header: 2.2
header files: 8.0
herror(): 9.7
hstrerror(): 9.7
htonl(): 3.2, 9.12, 9.12
htons(): 3.2, 3.3, 7.4, 9.12, 9.12
HTTP: 10.3
HTTP protocol: 2.1
ICMP: 8.0
IEEE-754: 7.4
INADDR_ANY:
INADDR_BROADCAST: 7.6
inet_addr(): 3.4, 9.13
inet_aton(): 3.4, 9.13
inet_ntoa(): 3.4, 9.13
inet_ntoa(): 3.4, 5.10
inet_pton(): 3.4
Internet Control Message Protocol: see ICMP.
Internet protocol: see IP.
Internet Relay Chat: see IRC.
ioctl(): 8.0
IP: 2.1, 2.2, 3.0, 3.4, 5.3, 5.8, 5.11, 10.3
IP address: 9.2, 9.6, 9.7, 9.9
IPv4: 3.1
IPv6: 3.1, 3.3, 3.4.1, 4.0
IRC: 7.4, 10.3
ISO/OSI: 2.2
layered network model: see ISO/OSI.
Linux: 1.5
listen(): 5.3, 5.5, 9.15
backlog: 5.5
with select(): 7.2
lo: see loopback device.
localhost: 8.0
loopback device: 8.0
man pages: 9.0
Maximum Transmission Unit: see MTU.
mirroring: 1.7
MSG_DONTROUTE: 9.21
MSG_DONTWAIT: 9.21
MSG_NOSIGNAL: 9.21
MSG_OOB: 9.18, 9.21
MSG_PEEK: 9.18
MSG_WAITALL: 9.18
MTU: 8.0
NAT: 3.4.1
netstat: 8.0, 8.0
network address translation: see NAT.
NNTP: 10.3
non-blocking sockets: 7.1, 9.1, 9.11, 9.21
ntohl(): 3.2, 9.12, 9.12
ntohs(): 3.2, 9.12, 9.12
O_ASYNC: see asynchronous I/O.
O_NONBLOCK: see non-blocking sockets.
OpenSSL: 8.0
out-of-band data: 9.18, 9.21
packet sniffer: 8.0
Pat: 7.6
perror(): 9.10, 9.16
PF_INET: 8.0, 9.23
ping: 8.0
poll(): 7.2, 9.17
port: 5.8, 9.2, 9.9
ports: 5.3, 5.3
private network: 3.4.1
promiscuous mode: 8.0
raw sockets: 2.1, 8.0
read(): 2.0
recv(): 2.0, 2.0, 5.7, 9.18
timeout: 8.0
recvfrom(): 5.8, 9.18
recvtimeout(): 8.0
references: 10.1
web-based: 10.2
RFCs: 10.3
route: 8.0
SA_RESTART: 8.0
Secure Sockets Layer: see SSL.
security: 8.0
select(): 1.5, 7.1, 7.2, 8.0, 8.0, 9.19
with listen(): 7.2
send(): 2.0, 2.0, 2.2, 5.7, 9.21
sendall(): 7.3, 7.5
sendto(): 2.2, 9.21
serialization: 7.4
server:
datagram: 6.3
stream: 6.1
setsockopt(): 5.3, 7.6, 8.0, 8.0, 9.20
shutdown(): 5.9, 9.22
sigaction(): 6.1, 8.0
SIGIO: 9.11
SIGPIPE: 9.4, 9.21
SIGURG: 9.18, 9.21
SMTP: 10.3
SO_BINDTODEVICE: 9.20
SO_BROADCAST: 7.6, 9.20
SO_RCVTIMEO: 8.0
SO_REUSEADDR: 5.3, 8.0, 9.20
SO_SNDTIMEO: 8.0
SOCK_DGRAM: see socket;datagram.
SOCK_RAW: 9.23
SOCK_STREAM: see socket;stream.
socket: 2.0
datagram: 2.1, 2.1, 2.2, 5.8, 9.18, 9.20, 9.21, 9.23
raw: 2.1
stream: 2.1, 2.1, 9.1, 9.18, 9.21, 9.23
types: 2.0, 2.1
socket descriptor: 2.0, 3.3
socket(): 2.0, 5.2, 9.23
SOL_SOCKET: 9.20
Solaris: 1.4, 9.20
SSL: 8.0
strerror(): 9.10, 9.16
SunOS: 1.4, 9.20
TCP: 2.1, 9.23, 10.3
gcc: 2.1, 10.3
TFTP: 2.2, 10.3
timeout, setting: 8.0
translations: 1.8
transmission control protocol: see TCP.
TRON: 5.4
UDP: 2.1, 2.2, 7.6, 9.23, 10.3
user datagram protocol: see UDP.
Vint Cerf: 3.1
Windows: 1.5, 5.9, 8.0, 9.4, 9.20
Winsock: 1.5, 5.9
Winsock FAQ: 1.5
write(): 2.0
WSACleanup(): 1.5
WSAStartup(): 1.5
zombie process: 6.1