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Networking Alan L. Cox [email protected] T. S. Eugene Ng [email protected] Some slides adapted from CMU 15.213 slides Objectives Be exposed to the basic underpinnings of the Internet Be able to use network socket interfaces effectively Be exposed to the basic underpinnings of the World Wide Web Cox & Ng Networking 2 The 2004 A. M. Turing Award Goes to... Cox & Ng Networking 3 The 2004 A. M. Turing Award Goes to... Bob Kahn Vint Cerf "For pioneering work on internetworking, including the design and implementation of the Internet's basic communications protocols, TCP/IP, and for inspired leadership in networking." The only Turing Award given to-date to recognize work in computer networking Cox & Ng Networking 4 But at the Same Time... Daily, e.g. 110 attacks from China; 26 attacks from USA 2/24/2008 YouTube traffic mis-routed to Pakistan Q2/2008 1000s of Netherlands DSL customers lost service due to network configuration error (Brazil) black-holed 11/10/2008 CTBC all Internet traffic in some parts of Brazil 2/16/2009 Supro (Czech) routing messages triggered a Cisco router bug world-wide 5/2009 AfNOG (Africa) routing messages triggered buffer overflow in open-source routing software Quagga world-wide Source: Akamai Technologies, Inc. Cox & Ng Networking 5 Telephony Interactive telecommunication between people Analog voice Transmitter/receiver continuously in contact with electronic circuit Electric current varies with acoustic pressure Analog/Continuous Signal Over electrical circuits Cox & Ng Networking 6 Telephony Milestones 1876: Alexander Bell invented telephone 1878: Public switches installed at New Haven and San Francisco, public switched telephone network is born People can talk without being on the same wire! Without Switch Cox & Ng With Switch Networking 7 Telephony Milestones 1878: First telephone directory; White House line 1881: Insulated, balanced twisted pair as local loop 1885: AT&T formed 1892: First automatic commercial telephone switch 1903: 3 million telephones in U.S. 1915: First transcontinental telephone line 1927: First commercial transatlantic commercial service Cox & Ng Networking 8 Telephony Milestones 1937: Multiplexing introduced for inter-city calls One link carries multiple conversations With Multiplexing Without Multiplexing Cox & Ng Networking 9 Data or Computer Networks Networks designed for computers to computers or devices vs. communication between human beings Digital information vs. analog voice Digital/Discrete Signal Not a continuous stream of bits, rather, discrete “packets” with lots of silence in between Dedicated circuit hugely inefficient Packet switching invented Cox & Ng Networking 10 Major Internet Milestones 1960-1964 Basic concept of “packet switching” was independently developed by Baran (RAND), Kleinrock (MIT) AT&T insisted that packet switching would never work! 1965 First time two computers talked to each other using packets (Roberts, MIT; Marill, SDC) dial-up MIT TX-2 Cox & Ng SDC Q32 Networking 11 Major Internet Milestones 1968 BBN group proposed to use Honeywell 516 mini-computers for the Interface Message Processors (i.e. packet switches) 1969 The first ARPANET message transmitted between UCLA (Kleinrock) and SRI (Engelbart) We sent an “L”, did you get the “L”? Yep! We sent an “O”, did you get the “O”? Yep! We sent a “G”, did you get the “G”? Crash! Cox & Ng Networking 12 Major Internet Milestones • 1970 First packet radio network ALOHANET (Abramson, U Hawaii) • 1973 Ethernet invented (Metcalfe, Xerox PARC) • Why is it called the “Inter-net”? • 1974 “A protocol for Packet Network Interconnection” published by Cerf and Kahn – First internetworking protocol TCP – This paper was cited for their Turing Award • 1977 First TCP operation over ARPANET, Packet Radio Net, and SATNET • 1985 NSF commissions NSFNET backbone • 1991 NSF opens Internet to commercial use Cox & Ng Networking 13 Internet Hourglass Architecture Email, Web, ssh,... TCP, UDP, … IP Ethernet, WiFi, 3G, bluetooth,... Cox & Ng Networking 14 A Client-Server Transaction Most network applications are based on the client-server model: A server process and one or more client processes Server manages some resource Server provides service by manipulating resource for clients 1. Client sends request Client process 4. Client handles response Server process 3. Server sends response Resource 2. Server handles request Note: clients and servers are processes running on hosts (can be the same or different hosts) Cox & Ng Networking 15 Network Hardware register file CPU chip ALU system bus memory bus main memory I/O bridge Bus Interface Expansion slots I/O bus USB controller mouse keyboard Cox & Ng graphics adapter disk controller network adapter disk network monitor Networking 16 Computer Networks A network is a hierarchical system of boxes and wires organized by geographical proximity Cluster network spans cluster or machine room • Switched Ethernet, Infiniband, Myrinet, … LAN (local area network) spans a building or campus • Ethernet is most prominent example WAN (wide-area network) spans very long distance • A high-speed point-to-point link • Leased line or SONET/SDH circuit, or MPLS/ATM circuit An internetwork (internet) is an interconnected set of networks The Global IP Internet (uppercase “I”) is the most famous example of an internet (lowercase “i”) Cox & Ng Networking 17 Lowest Level: Ethernet Segment Ethernet segment consists of a collection of hosts connected by wires (twisted pairs) to a hub host host 100 Mb/s host 100 Mb/s hub ports Operation Each Ethernet adapter has a unique 48-bit address Hosts send bits to any other host in chunks called frames Hub slavishly copies each bit from each port to every other port • Every host sees every bit Note: Hubs are largely obsolete • Bridges (switches, routers) became cheap enough to replace them (don’t broadcast all traffic) Cox & Ng Networking 18 Next Level: Bridged Ethernet Segment Spans room, building, or campus Bridges cleverly learn which hosts are reachable from which ports and then selectively copy frames from port to port host host host host bridge hub 100 Mb/s hub 100 Mb/s 1-10 Gb/s host host Cox & Ng 1 Gb/s 1 Gb/s host bridge 1 Gb/s host Networking host host bridge host host 19 Conceptual View of LANs For simplicity, hubs, bridges, and wires are often shown as a collection of hosts attached to a single wire: host Cox & Ng host ... host Networking 20 Next Level: internets Multiple incompatible LANs can be physically connected by specialized computers called routers The connected networks are called an internet host host ... host host host ... LAN 1 host LAN 2 router WAN router WAN router LAN 1 and LAN 2 might be completely different, totally incompatible LANs (e.g., Ethernet and WiFi, 802.11*, T1-links, DSL, …) Cox & Ng Networking 21 The Internet Circa 1986 In 1986, the Internet consisted of one backbone (NSFNET) that connected 13 sites via 45 Mbps T3 links Merit (Univ of Mich) BARRNet (Palo Alto) NCSA (Illinois) MidNet (Lincoln, NE) Cornell Theory Center WestNet (Salt Lake City) Pittsburgh NorthwestNet (Seattle) Supercomputing Center San Diego Supercomputing Center John von Neumann Center (Princeton) SESQUINET (Rice) SURANET (Georgia Tech) Connecting to the Internet involved connecting one of your routers to a router at a backbone site, or to a regional network that was already connected to the backbone Cox & Ng Networking 22 NSFNET Internet Backbone source: www.eef.org Cox & Ng Networking 23 After NSFNET Early 90s Commercial enterprises began building their own high-speed backbones Backbone would connect to NSFNET, sell access to companies, ISPs, and individuals 1995 NSFNET decommissioned NSF fostered the creation of network access points (NAPs) to interconnect the commercial backbones Cox & Ng Networking 24 Current Internet Architecture Cox & Ng Networking 25 Level 3 Backbone Cox & Ng Networking 26 AT&T Backbone Cox & Ng Networking 27 Submarine Cabling Cox & Ng Networking 28 The Notion of an internet Protocol How is it possible to send bits across incompatible LANs and WANs? Solution: protocol software running on each host and router smoothes out the differences between the different networks Implements an internet protocol (i.e., set of rules) that governs how hosts and routers should cooperate when they transfer data from network to network TCP/IP is the protocol for the global IP Internet Cox & Ng Networking 29 What Does an internet Protocol Do? 1. Provides a naming scheme An internet protocol defines a uniform format for host addresses Each host (and router) is assigned at least one of these internet addresses that uniquely identifies it 2. Provides a delivery mechanism An internet protocol defines a standard transfer unit (packet) Packet consists of header and payload • Header: contains info such as packet size, source and destination addresses • Payload: contains data bits sent from source host Cox & Ng Networking 30 Transferring Data Over an internet (1) client server protocol software data data LAN1 adapter PH FH1 (4) Router LAN1 adapter LAN1 data (8) data (7) data PH FH2 (6) data PH FH2 protocol software PH FH1 LAN1 frame (3) Host B data internet packet (2) Host A LAN2 adapter PH FH1 LAN2 adapter LAN2 frame data LAN2 PH FH2 (5) protocol software Cox & Ng Networking 31 Other Issues We are glossing over a number of important questions: What if different networks have different maximum frame sizes? (segmentation) How do routers know where to forward frames? How are routers informed when the network topology changes? What if packets get lost? We’ll leave the discussion of these question to computer networking classes (COMP 429) Cox & Ng Networking 32 Global IP Internet Based on the TCP/IP protocol family IP (Internet protocol) : • Provides basic naming scheme and unreliable delivery capability of packets (datagrams) from host-to-host UDP (Unreliable Datagram Protocol) • Uses IP to provide unreliable datagram delivery from process-to-process TCP (Transmission Control Protocol) • Uses IP to provide reliable byte streams from process-to-process over connections Accessed via a mix of Unix file I/O and functions from the sockets interface Cox & Ng Networking 33 Organization of an Internet Application Internet client Internet server Client User code Server TCP/IP Kernel code TCP/IP Sockets interface (system calls) Hardware interface (interrupts) Network adapter Hardware and firmware Network adapter Global IP Internet Cox & Ng Networking 34 A Programmer’s View of the Internet Hosts are mapped to a set of 32-bit IP addresses 128.42.1.125 (4 * 8 bits) A set of identifiers called Internet domain names are mapped to the set of IP addresses for convenience www.cs.rice.edu is mapped to 128.42.1.125 A process on one Internet host can communicate with a process on another Internet host over a connection Cox & Ng Networking 35 IP Addresses 32-bit IP addresses are stored in an IP address struct IP addresses are always stored in memory in network byte order (big-endian byte order) True in general for any integer transferred in a packet header from one machine to another • E.g., the port number used to identify an Internet connection /* Internet address structure */ struct in_addr { unsigned int s_addr; /* network byte order (big-endian) */ }; Handy network byte-order conversion functions: htonl: convert long int from host to network byte order htons: convert short int from host to network byte order ntohl: convert long int from network to host byte order ntohs: convert short int from network to host byte order Cox & Ng Networking 36 Dotted Decimal Notation By convention, each byte in a 32-bit IP address is represented by its decimal value and separated by a period • IP address 0x8002C2F2 = 128.2.194.242 Functions for converting between binary IP addresses and dotted decimal strings: inet_aton: converts a dotted decimal string to an IP address in network byte order inet_ntoa: converts an IP address in network by order to its corresponding dotted decimal string “n” denotes network representation, “a” denotes application representation Cox & Ng Networking 37 IP Address Structure IP (V4) Address space divided into classes: 0123 Class A 0 Net ID Class B 1 0 Class C 1 1 0 Class D 1 1 1 0 Class E 1 1 1 1 8 16 24 31 Host ID Net ID Host ID Net ID Host ID Multicast address Reserved for experiments Special Addresses for routers and gateways (all 0/1’s) Loop-back address: 127.0.0.1 Unrouted (private) IP addresses: 10.0.0.0/8, 172.16.0.0/12, 192.168.0.0/16 Dynamic IP addresses (DHCP) Cox & Ng Networking 38 Internet Domain Names unnamed root .net .edu mit rice clear crystal 128.42.151.14 128.42.151.13 .com berkeley cs bell Cox & Ng .gov amazon www 72.21.210.11 Networking First-level domain names Second-level domain names Third-level domain names 39 Domain Naming System (DNS) The Internet maintains a mapping between IP addresses and domain names in a huge worldwide distributed database called DNS Conceptually, programmers can view the DNS database as a collection of millions of host entry structures: /* DNS host entry structure struct hostent { char *h_name; /* char **h_aliases; /* int h_addrtype; /* int h_length; /* char **h_addr_list; /* }; */ official domain name of host */ null-terminated array of domain names */ host address type (AF_INET) */ length of an address, in bytes */ null-terminated array of in_addr structs */ Functions for retrieving host entries from DNS: gethostbyname: query key is a DNS domain name gethostbyaddr: query key is an IP address Cox & Ng Networking 40 Properties of DNS Host Entries Each host entry is an equivalence class of domain names and IP addresses Each host has a locally defined domain name localhost which always maps to the loopback address 127.0.0.1 Different kinds of mappings are possible: Simple case: 1 domain name maps to one IP address: • forest.owlnet.rice.edu maps to 10.130.195.71 Multiple domain names mapped to the same IP address: • www.cs.rice.edu, ececs.rice.edu, and bianca.cs.rice.edu all map to 128.42.1.125 Multiple domain names mapped to multiple IP addresses: • aol.com and www.aol.com map to multiple IP addresses Some valid domain names don’t map to any IP address: • for example: clear.rice.edu Cox & Ng Networking 41 A Program That Queries DNS int main(int argc, char **argv) { /* argv[1] is a domain name */ char **pp; /* or dotted decimal IP addr */ struct in_addr addr; struct hostent *hostp; if (inet_aton(argv[1], &addr) != 0) hostp = Gethostbyaddr((const char *)&addr, sizeof(addr), AF_INET); else hostp = Gethostbyname(argv[1]); printf("official hostname: %s\n", hostp->h_name); for (pp = hostp->h_aliases; *pp != NULL; pp++) printf("alias: %s\n", *pp); for (pp = hostp->h_addr_list; *pp != NULL; pp++) { addr.s_addr = *((unsigned int *)*pp); printf("address: %s\n", inet_ntoa(addr)); } } Cox & Ng Networking 42 Querying DNS Domain Information Groper (dig) provides a scriptable command line interface to DNS Available on CLEAR Lots of web interfaces (google “domain information groper”) unix> dig +short bianca.cs.rice.edu 128.42.1.125 unix> dig +short -x 128.42.1.125 bianca.cs.rice.edu. unix> dig +short google.com 72.14.207.99 64.233.187.99 64.233.167.99 unix> dig +short -x 64.233.167.99 py-in-f99.google.com. Cox & Ng Networking 43 Internet Connections Clients and servers communicate by sending streams of bytes over connections: Point-to-point, full-duplex (2-way communication), and reliable A socket is an endpoint of a connection Socket address is an IP address, port pair A port is a 16-bit integer that identifies a process: Ephemeral port: Assigned automatically on client when client makes a connection request Well-known port: Associated with some service provided by a server (e.g., port 80 is associated with Web servers) A connection is uniquely identified by the socket addresses of its endpoints (socket pair) (cliaddr:cliport, servaddr:servport) Cox & Ng Networking 44 Putting it all Together: Anatomy of an Internet Connection Client socket address 128.2.194.242:51213 Client Server socket address 208.216.181.15:80 Connection socket pair (128.2.194.242:51213, 208.216.181.15:80) Client host address 128.2.194.242 Cox & Ng Server (port 80) Server host address 208.216.181.15 Networking 45 Clients Examples of client programs Web browsers, ftp, telnet, ssh How does a client find the server? The IP address in the server socket address identifies the host (more precisely, an adapter on the host) The (well-known) port in the server socket address identifies the service, and thus implicitly identifies the server process that performs that service Examples of well known ports • • • • Cox & Ng Port Port Port Port 7: Echo server 23: Telnet server 25: Mail server 80: Web server Networking 46 Using Ports to Identify Services Server host 128.2.194.242 Client host Service request for 128.2.194.242:80 (i.e., the Web server) Client Web server (port 80) Kernel Echo server (port 7) Client Service request for 128.2.194.242:7 (i.e., the echo server) Web server (port 80) Kernel Echo server (port 7) Cox & Ng Networking 47 Servers Servers are long-running processes (daemons) Created at boot-time (typically) by the init process (process 1) Run continuously until the machine is turned off Each server waits for requests to arrive on a well-known port associated with a particular service Port Port Port Port 7: echo server 23: telnet server 25: mail server 80: HTTP server A machine that runs a server process is also often referred to as a “server” Cox & Ng Networking 48 Server Examples Web server (port 80) Resource: files/compute cycles (CGI programs) Service: retrieves files and runs CGI programs on behalf of the client FTP server (20, 21) Resource: files See /etc/services for a comprehensive list of the services available on a UNIX machine Service: stores and retrieve files Telnet server (23) Resource: terminal Service: proxies a terminal on the server machine Mail server (25) Resource: email “spool” file Service: stores mail messages in spool file Cox & Ng Networking 49 Sockets Interface Created in the early 80’s as part of the original Berkeley distribution of Unix that contained an early version of the Internet protocols Provides a user-level interface to the network Underlying basis for all Internet applications Based on client/server programming model Cox & Ng Networking 50 Overview of the Sockets Interface Client Server socket socket bind open_listenfd open_clientfd listen connect Connection request rio_writen rio_readlineb rio_readlineb close Cox & Ng accept rio_writen EOF rio_readlineb Networking close Await connection request from next client 51 Sockets What is a socket? To the kernel, a socket is an endpoint of communication To an application, a socket is a file descriptor that lets the application read/write from/to the network • Remember: all Unix I/O devices, including networks, are modeled as files Clients and servers communicate with each other by reading from and writing to socket descriptors The main distinction between regular file I/O and socket I/O is how the application “opens” the socket descriptors Cox & Ng Networking 52 Socket Address Structures Generic socket address: Address for connect, bind, and accept C did not have generic (void *) pointers when the sockets interface was designed struct sockaddr { unsigned short sa_family; char sa_data[14]; }; /* protocol family */ /* address data. */ Internet-specific socket address: Must cast (sockaddr_in *) to (sockaddr *) struct sockaddr_in { unsigned short sin_family; unsigned short sin_port; struct in_addr sin_addr; unsigned char sin_zero[8]; }; Cox & Ng /* /* /* /* address family (always AF_INET) */ port num in network byte order */ IP addr in network byte order */ pad to sizeof(struct sockaddr) */ Networking 53 Echo Client Main Routine int main(int argc, char **argv) /* usage: ./echoclient host port */ { int clientfd, port; char *host, buf[MAXLINE]; rio_t rio; host = argv[1]; port = atoi(argv[2]); clientfd = Open_clientfd(host, port); Rio_readinitb(&rio, clientfd); while (Fgets(buf, MAXLINE, stdin) != NULL) { Rio_writen(clientfd, buf, strlen(buf)); Rio_readlineb(&rio, buf, MAXLINE); Fputs(buf, stdout); } Close(clientfd); exit(0); } Cox & Ng Networking 54 Echo Client: open_clientfd int open_clientfd(char *hostname, int port) { int clientfd; This function opens a struct hostent *hp; connection from the client to struct sockaddr_in serveraddr; the server at hostname:port if ((clientfd = socket(AF_INET, SOCK_STREAM, 0)) < 0) return -1; /* check errno for cause of error */ /* Fill in the server's IP address and port */ if ((hp = gethostbyname(hostname)) == NULL) return -2; /* check h_errno for cause of error */ bzero((char *) &serveraddr, sizeof(serveraddr)); serveraddr.sin_family = AF_INET; bcopy((char *)hp->h_addr, (char *)&serveraddr.sin_addr.s_addr, hp->h_length); serveraddr.sin_port = htons(port); /* Establish a connection with the server */ if (connect(clientfd, (SA *) &serveraddr, sizeof(serveraddr)) < 0) return -1; return clientfd; } Cox & Ng Networking 55 open_clientfd (socket) socket creates a socket descriptor on the client AF_INET: indicates that the socket is associated with Internet protocols SOCK_STREAM: selects a reliable byte stream connection int clientfd; /* socket descriptor */ if ((clientfd = socket(AF_INET, SOCK_STREAM, 0)) < 0) return -1; /* check errno for cause of error */ ... (more) Cox & Ng Networking 56 open_clientfd (gethostbyname) The client then builds the server’s Internet address int clientfd; /* socket descriptor */ struct hostent *hp; /* DNS host entry */ struct sockaddr_in serveraddr; /* server’s IP address */ ... /* fill in the server's IP address and port */ if ((hp = gethostbyname(hostname)) == NULL) return -2; /* check h_errno for cause of error */ bzero((char *) &serveraddr, sizeof(serveraddr)); serveraddr.sin_family = AF_INET; bcopy((char *)hp->h_addr, (char *)&serveraddr.sin_addr.s_addr, hp->h_length); serveraddr.sin_port = htons(port); Cox & Ng Networking 57 open_clientfd (connect) Finally the client creates a connection with the server Client process suspends (blocks) until the connection is created After resuming, the client is ready to begin exchanging messages with the server via Unix I/O calls on descriptor clientfd int clientfd; /* socket descriptor */ struct sockaddr_in serveraddr; /* server address */ typedef struct sockaddr SA; /* generic sockaddr */ ... /* Establish a connection with the server */ if (connect(clientfd, (SA *)&serveraddr, sizeof(serveraddr)) < 0) return -1; return clientfd; Cox & Ng Networking 58 Echo Server: Main Routine int main(int argc, char **argv) { int listenfd, connfd, port, clientlen; struct sockaddr_in clientaddr; struct hostent *hp; char *haddrp; port = atoi(argv[1]); /* the server listens on the given port */ listenfd = open_listenfd(port); while (1) { clientlen = sizeof(clientaddr); connfd = Accept(listenfd, (SA *)&clientaddr, &clientlen); hp = Gethostbyaddr((const char *)&clientaddr.sin_addr.s_addr, sizeof(clientaddr.sin_addr.s_addr), AF_INET); haddrp = inet_ntoa(clientaddr.sin_addr); printf("server connected to %s (%s)\n", hp->h_name, haddrp); echo(connfd); Close(connfd); } } Cox & Ng Networking 59 Echo Server: open_listenfd int open_listenfd(int port) { int listenfd, optval=1; struct sockaddr_in serveraddr; /* Create a socket descriptor */ if ((listenfd = socket(AF_INET, SOCK_STREAM, 0)) < 0) return -1; /* Eliminates "Address already in use" error from bind. */ if (setsockopt(listenfd, SOL_SOCKET, SO_REUSEADDR, (const void *)&optval , sizeof(int)) < 0) return -1; ... (more) Cox & Ng Networking 60 Echo Server: open_listenfd (cont) ... /* Listenfd will be an endpoint for all requests to port on any IP address for this host */ bzero((char *) &serveraddr, sizeof(serveraddr)); serveraddr.sin_family = AF_INET; serveraddr.sin_addr.s_addr = htonl(INADDR_ANY); serveraddr.sin_port = htons((unsigned short)port); if (bind(listenfd, (SA *)&serveraddr, sizeof(serveraddr)) < 0) return -1; /* Make it a listening socket ready to accept connection requests */ if (listen(listenfd, LISTENQ) < 0) return -1; return listenfd; } Cox & Ng Networking 61 open_listenfd (socket) socket creates a socket descriptor on the server AF_INET: indicates that the socket is associated with Internet protocols SOCK_STREAM: selects a reliable byte stream connection int listenfd; /* listening socket descriptor */ /* Create a socket descriptor */ if ((listenfd = socket(AF_INET, SOCK_STREAM, 0)) < 0) return -1; Cox & Ng Networking 62 open_listenfd (setsockopt) The socket can be given some attributes ... /* Eliminates "Address already in use" error from bind(). */ if (setsockopt(listenfd, SOL_SOCKET, SO_REUSEADDR, (const void *)&optval , sizeof(int)) < 0) return -1; Handy trick that allows us to rerun the server immediately after we kill it Otherwise we would have to wait about 30 secs Eliminates “Address already in use” error from bind() Strongly suggest you do this for all your servers to simplify debugging Cox & Ng Networking 63 open_listenfd (init socket address) Next, we initialize the socket with the server’s Internet address (IP address and port) struct sockaddr_in serveraddr; /* server's socket addr */ ... /* listenfd will be an endpoint for all requests to port on any IP address for this host */ bzero((char *) &serveraddr, sizeof(serveraddr)); serveraddr.sin_family = AF_INET; serveraddr.sin_addr.s_addr = htonl(INADDR_ANY); serveraddr.sin_port = htons((unsigned short)port); IP address and port stored in network (big-endian) byte order htonl() converts longs from host byte order to network byte order htons() convers shorts from host byte order to network byte order Cox & Ng Networking 64 open_listenfd (bind) bind associates the socket with the socket address we just created int listenfd; /* listening socket */ struct sockaddr_in serveraddr; /* server’s socket addr */ ... /* listenfd will be an endpoint for all requests to port on any IP address for this host */ if (bind(listenfd, (SA *)&serveraddr, sizeof(serveraddr)) < 0) return -1; Cox & Ng Networking 65 open_listenfd (listen) listen indicates that this socket will accept connection (connect) requests from clients int listenfd; /* listening socket */ ... /* Make it a listening socket ready to accept connection requests */ if (listen(listenfd, LISTENQ) < 0) return -1; return listenfd; } We’re finally ready to enter the main server loop that accepts and processes client connection requests Cox & Ng Networking 66 Echo Server: Main Loop The server loops endlessly, waiting for connection requests, then reading input from the client, and echoing the input back to the client main() { /* create and configure the listening socket */ while(1) { /* Accept(): wait for a connection request */ /* echo(): read and echo input lines from client til EOF */ /* Close(): close the connection */ } } Cox & Ng Networking 67 Echo Server: accept accept() blocks waiting for a connection request int listenfd; /* listening descriptor */ int connfd; /* connected descriptor */ struct sockaddr_in clientaddr; int clientlen; clientlen = sizeof(clientaddr); connfd = Accept(listenfd, (SA *)&clientaddr, &clientlen); accept returns a connected descriptor (connfd) with the same properties as the listening descriptor (listenfd) Returns when the connection between client and server is created and ready for I/O transfers All I/O with the client will be done via the connected socket accept also fills in client’s IP address Cox & Ng Networking 68 Echo Server: accept Illustrated listenfd(3) Server Client clientfd Connection request Client listenfd(3) Server clientfd listenfd(3) Client clientfd Cox & Ng 1. Server blocks in accept, waiting for connection request on listening descriptor listenfd Server connfd(4) Networking 2. Client makes connection request by calling and blocking in connect 3. Server returns connfd from accept. Client returns from connect. Connection is now established between clientfd and connfd 69 Connected vs. Listening Descriptors Listening descriptor End point for client connection requests Created once and exists for lifetime of the server Connected descriptor End point of the connection between client and server A new descriptor is created each time the server accepts a connection request from a client Exists only as long as it takes to service client Why the distinction? Allows for concurrent servers that can communicate over many client connections simultaneously • E.g., Each time we receive a new request, we fork a child to handle the request Cox & Ng Networking 70 Echo Server: Identifying the Client The server can determine the domain name and IP address of the client struct hostent *hp; char *haddrp; /* pointer to DNS host entry */ /* pointer to dotted decimal string */ hp = Gethostbyaddr((const char *)&clientaddr.sin_addr.s_addr, sizeof(clientaddr.sin_addr.s_addr), AF_INET); haddrp = inet_ntoa(clientaddr.sin_addr); printf("server connected to %s (%s)\n", hp->h_name, haddrp); Cox & Ng Networking 71 Echo Server: echo The server uses RIO to read and echo text lines until EOF (end-of-file) is encountered EOF notification caused by client calling close(clientfd) IMPORTANT: EOF is a condition, not a particular data byte void echo(int connfd) { size_t n; char buf[MAXLINE]; rio_t rio; Rio_readinitb(&rio, connfd); while((n = Rio_readlineb(&rio, buf, MAXLINE)) != 0) { printf("server received %d bytes\n", n); Rio_writen(connfd, buf, n); } } Cox & Ng Networking 72 Testing Servers Using telnet The telnet program is invaluable for testing servers that transmit ASCII strings over Internet connections Our simple echo server Web servers Mail servers Usage: unix> telnet <host> <portnumber> Creates a connection with a server running on <host> and listening on port <portnumber> Cox & Ng Networking 73 Testing the Echo Server With telnet bass> echoserver 5000 server established connection with KITTYHAWK.CMCL (128.2.194.242) server received 5 bytes: 123 server established connection with KITTYHAWK.CMCL (128.2.194.242) server received 8 bytes: 456789 kittyhawk> telnet bass 5000 Trying 128.2.222.85... Connected to BASS.CMCL.CS.CMU.EDU. Escape character is '^]'. 123 123 Connection closed by foreign host. kittyhawk> telnet bass 5000 Trying 128.2.222.85... Connected to BASS.CMCL.CS.CMU.EDU. Escape character is '^]'. 456789 456789 Connection closed by foreign host. kittyhawk> Cox & Ng Networking 74 Running the Echo Client and Server bass> echoserver 5000 server established connection with KITTYHAWK.CMCL (128.2.194.242) server received 4 bytes: 123 server established connection with KITTYHAWK.CMCL (128.2.194.242) server received 7 bytes: 456789 ... kittyhawk> echoclient bass 5000 Please enter msg: 123 Echo from server: 123 kittyhawk> echoclient bass 5000 Please enter msg: 456789 Echo from server: 456789 kittyhawk> Cox & Ng Networking 75 For More Information W. Richard Stevens, “Unix Network Programming: Networking APIs: Sockets and XTI”, Volume 1, Second Edition, Prentice Hall, 1998. THE network programming bible Complete versions of the echo client and server are developed in the text Available on the course web site You should compile and run them for yourselves to see how they work Feel free to borrow any of this code Cox & Ng Networking 76 Web History 1945: Vannevar Bush, “As we may think”, Atlantic Monthly, July, 1945 • Describes the idea of a distributed hypertext system • A “memex” that mimics the “web of trails” in our minds 1989: Tim Berners-Lee (CERN) writes internal proposal to develop a distributed hypertext system • Connects “a web of notes with links” • Intended to help CERN physicists in large projects share and manage information 1990: Tim Berners-Lee writes a graphical browser for Next machines Cox & Ng Networking 77 Web History (cont) 1992 NCSA server released 26 WWW servers worldwide 1993 Marc Andreessen releases first version of NCSA Mosaic browser Mosaic version released for (Windows, Mac, Unix) Web (port 80) traffic at 1% of NSFNET backbone traffic Over 200 WWW servers worldwide 1994 Andreessen and colleagues leave NCSA to form "Mosaic Communications Corp" (became Netscape, then part of AOL) Cox & Ng Networking 78 Internet Hosts ISC Domain Survey Host Count 600,000,000 500,000,000 400,000,000 300,000,000 200,000,000 100,000,000 Jan-08 Jan-07 Jan-06 Jan-05 Jan-04 Jan-03 Jan-02 Jan-01 Jan-00 Jan-99 Jan-98 0 Source: www.isc.org Cox & Ng Networking 79 Web Servers Clients and servers communicate using the HyperText Transfer Protocol (HTTP) Client and server HTTP request establish TCP connection Client requests content Server responds with requested content Client and server (may) close connection Web client (browser) Web server HTTP response (content) Current version is HTTP/1.1 RFC 2616, June, 1999 Cox & Ng Networking 80 Web Content Web servers return content to clients content: a sequence of bytes with an associated MIME (Multipurpose Internet Mail Extensions) type Example MIME types HTML document text/plain Unformatted text application/postscript Postcript document image/gif Binary image (GIF format) image/jpeg Binary image (JPEG format) text/html Cox & Ng Networking 81 Static and Dynamic Content The content returned in HTTP responses can be either static or dynamic Static content: content stored in files and retrieved in response to an HTTP request • Examples: HTML files, images, audio clips Dynamic content: content produced on-the-fly in response to an HTTP request • Example: content produced by a program executed by the server on behalf of the client (i.e., search results) Bottom line: All Web content is associated with a file that is managed by the server Cox & Ng Networking 82 URLs Each file managed by a server has a unique name called a URL (Universal Resource Locator) URLs for static content: http://www.rice.edu:80/index.html http://www.rice.edu/index.html http://www.rice.edu • Identifies a file called index.html, managed by a Web server at www.rice.edu that is listening on port 80 URLs for dynamic content: http://www.cs.cmu.edu:8000/cgi-bin/adder?15000&213 • Identifies an executable file called adder, managed by a Web server at www.cs.cmu.edu that is listening on port 8000, that should be called with two argument strings: 15000 and 213 Cox & Ng Networking 83 How Clients and Servers Use URLs Example URL: http://www.aol.com:80/index.html Clients use prefix (http://www.aol.com:80) to infer: What kind of server to contact (http (Web) server) Where the server is (www.aol.com) What port the server is listening on (80) Servers use suffix (/index.html) to: Determine if request is for static or dynamic content • No hard and fast rules for this • Convention: executables reside in cgi-bin directory Find file on file system • Initial “/” in suffix denotes home directory for requested content • Minimal suffix is “/”, which servers expand to some default home page (e.g., index.html) Cox & Ng Networking 84 Anatomy of an HTTP Transaction unix> telnet www.google.com 80 Trying 209.85.164.104... Connected to www.l.google.com. Escape character is '^]'. GET / HTTP/1.1 host: www.google.com Client: open connection to server Telnet prints 3 lines to the terminal Client: request line Client: required HTTP/1.1 HOST header Client: empty line terminates headers HTTP/1.1 200 OK Server: response line Cache-Control: private Server: followed by six response headers Content-Type: text/html; charset=ISO-8859-1 Set-Cookie: PREF=ID=<..snip..> Server: gws Transfer-Encoding: chunked Date: Tue, 13 Nov 2007 17:25:04 GMT Server: empty line (“\r\n”) terminates hdrs <html> Server: first HTML line in response body <..snip..> Server: HTML content not shown. </html> Server: last HTML line in response body Connection closed by foreign host. Server: closes connection unix> Client: closes connection and terminates Cox & Ng Networking 85 HTTP Requests HTTP request is a request line, followed by zero or more request headers Request line: <method> <uri> <version> <method> is either GET, POST, OPTIONS, HEAD, PUT, DELETE, or TRACE <uri> is typically URL for proxies, URL suffix for servers <version> is HTTP version of request (HTTP/1.0 or HTTP/1.1) Cox & Ng Networking 86 HTTP Requests (cont) HTTP methods: GET: Retrieve static or dynamic content • Arguments for dynamic content are in URI • Workhorse method (99% of requests) POST: Retrieve dynamic content • Arguments for dynamic content are in the request body OPTIONS: Get server or file attributes HEAD: Like GET but no data in response body PUT: Write a file to the server! DELETE: Delete a file on the server! TRACE: Echo request in response body • Useful for debugging Cox & Ng Networking 87 HTTP Requests (cont) Request headers: <header name>: <header data> Provide additional information to the server Major differences between HTTP/1.1 and HTTP/1.0 HTTP/1.0 uses a new connection for each transaction HTTP/1.1 also supports persistent connections • Multiple transactions over the same connection • Connection: Keep-Alive HTTP/1.1 requires HOST header • Host: www.yahoo.com HTTP/1.1 adds additional support for caching Cox & Ng Networking 88 HTTP Responses HTTP response is a response line followed by zero or more response headers Response line: <version> <status code> <status msg> <version> is HTTP version of the response <status code> is numeric status <status msg> is corresponding English text • 200 • 403 • 404 OK Forbidden Not found Request was handled without error Server lacks permission to access file Server couldn’t find the file Response headers: <header name>: <header data> Provide additional information about response Content-Type: MIME type of content in response body Content-Length: Length of content in response body Cox & Ng Networking 89 GET Request to Apache Server From Firefox Browser GET /~comp221/proxytest.html HTTP/1.1 Host: www.owlnet.rice.edu User-Agent: Mozilla/5.0 (X11; U; Linux i686; en-US; rv:1.8.1.8) Gecko/20071022 Ubuntu/7.10 (gutsy) Firefox/2.0.0.8 Accept: text/xml,application/xml,application/xhtml+xml,text/html; q=0.9,text/plain;q=0.8,image/png,*/*;q=0.5 Accept-Language: en-us,en;q=0.5 Accept-Encoding: gzip,deflate Accept-Charset: ISO-8859-1,utf-8;q=0.7,*;q=0.7 Connection: keep-alive Keep-Alive: 300 CRLF (\r\n) Cox & Ng Networking 90 GET Response From Apache Server HTTP/1.1 200 OK Date: Tue, 13 Nov 2007 18:09:01 GMT Server: Apache/1.3.26 (Unix) mod_ssl/2.8.9 OpenSSL/0.9.6e Last-Modified: Tue, 13 Nov 2007 18:08:44 GMT ETag: “ac330311-df-4739e82c" Accept-Ranges: bytes Content-Length: 212 Connection: close Content-Type: text/html CRLF <html> <head><title>COMP221 Web Proxy Test Page</title></head> <body><h1>COMP221 Web Proxy Test Page</h1> This page is a simple text-only HTML file that can be used to test your web proxy software. </body></html> Cox & Ng Networking 91 Serving Dynamic Content Client sends request to server Server parses request URI to determine if request is for static or dynamic content GET /cgi-bin/env.pl HTTP/1.1 Client Server In the “old” days, this was as simple as the string “/cgi-bin” starting the URL Web servers are far more flexible and configurable now Cox & Ng Networking 92 Serving Dynamic Content (cont) The server creates a child process and runs the program identified by the URI in that process Client Server fork/exec env.pl Cox & Ng Networking 93 Serving Dynamic Content (cont) The child runs and generates the dynamic content Client The server captures the content of the child and forwards it without modification to the client Cox & Ng Networking Content Server Content env.pl 94 Issues in Serving Dynamic Content How does the client pass program arguments to the server? Request How does the server pass these arguments to the child? How does the server pass other info relevant to the request to the child? Client Content Server Content How does the server capture the content produced by the child? Create env.pl These issues are addressed by the Common Gateway Interface (CGI) specification Cox & Ng Networking 95 CGI Because the children are written according to the CGI spec, they are often called CGI programs Because many CGI programs are written in Perl, they are often called CGI scripts However, CGI really defines a simple standard for transferring information between the client (browser), the server, and the child process Cox & Ng Networking 96 add.com: THE Internet addition portal! Ever need to add two numbers together and you just can’t find your calculator? Try the addition service at “add.com: THE Internet addition portal!” Takes as input the two numbers you want to add together Returns their sum in a tasteful personalized message Cox & Ng Networking 97 The add.com Experience input URL host port CGI program args Output page Cox & Ng Networking 98 Serving Dynamic Content With GET Question: How does the to the server? Answer: The arguments URI Can be encoded directly browser or a URL in an client pass arguments are appended to the in a URL typed to a HTML link http://add.com/cgi-bin/adder?1&2 adder is the CGI program on the server that will do the addition argument list starts with “?” arguments separated by “&” spaces represented by “+” or “%20” Can also be generated by an HTML form <form method=get action="http://add.com/cgi-bin/postadder"> Cox & Ng Networking 99 Serving Dynamic Content With GET URL: http://add.com/cgi-bin/adder?1&2 Result displayed on browser: Welcome to add.com: THE Internet addition portal. The answer is: 1 + 2 = 3 Thanks for visiting! Tell your friends. Cox & Ng Networking 100 Serving Dynamic Content With GET Question: How does the server pass these arguments to the child? Answer: In environment variable QUERY_STRING A single string containing everything after the “?” For add.com: QUERY_STRING = “1&2” /* child code that accesses the argument list */ if ((buf = getenv("QUERY_STRING")) == NULL) { exit(1); } /* extract arg1 and arg2 from buf and convert */ ... n1 = atoi(arg1); n2 = atoi(arg2); Cox & Ng Networking 101 Serving Dynamic Content With GET Question: How does the server pass other info relevant to the request to the child? Answer: In a collection of environment variables defined by the CGI spec Cox & Ng Networking 102 Some CGI Environment Variables General SERVER_SOFTWARE SERVER_NAME GATEWAY_INTERFACE (CGI version) Request-specific SERVER_PORT REQUEST_METHOD (GET, POST, etc) QUERY_STRING (contains GET arguments) REMOTE_HOST (domain name of client) REMOTE_ADDR (IP address of client) CONTENT_TYPE (for POST, type of data in message body, e.g., text/html) CONTENT_LENGTH (length in bytes) Cox & Ng Networking 103 Some CGI Environment Variables In addition, the value of each header of type type received from the client is placed in environment variable HTTP_type Examples: • HTTP_ACCEPT • HTTP_HOST • HTTP_USER_AGENT (any “-” is changed to “_”) Cox & Ng Networking 104 Serving Dynamic Content With GET Question: How does the server capture the content produced by the child? Answer: The child generates its output on stdout Server uses dup2 to redirect stdout to its connected socket Notice that only the child knows the type and size of the content, so the child (not the server) must generate the corresponding headers /* child generates the result string */ sprintf(content, "Welcome to add.com: THE Internet addition portal\ <p>The answer is: %d + %d = %d\ <p>Thanks for visiting!\r\n", n1, n2, n1+n2); /* child generates the headers and dynamic content */ printf("Content-length: %d\r\n", strlen(content)); printf("Content-type: text/html\r\n"); printf("\r\n"); printf("%s", content); Cox & Ng Networking 105 Serving Dynamic Content With GET bass> ./tiny 8000 GET /cgi-bin/adder?1&2 HTTP/1.1 Host: bass.cmcl.cs.cmu.edu:8000 <CRLF> HTTP request received by Tiny Web server kittyhawk> telnet bass 8000 Trying 128.2.222.85... Connected to BASS.CMCL.CS.CMU.EDU. Escape character is '^]'. GET /cgi-bin/adder?1&2 HTTP/1.1 Host: bass.cmcl.cs.cmu.edu:8000 HTTP request sent by client <CRLF> HTTP/1.1 200 OK HTTP response generated by Server: Tiny Web Server the server Content-length: 102 HTTP response generated by Content-type: text/html the CGI program <CRLF> Welcome to add.com: THE Internet addition portal. <p>The answer is: 1 + 2 = 3 <p>Thanks for visiting! Connection closed by foreign host. kittyhawk> Cox & Ng Networking 106 Proxies A proxy is an intermediary between a client and an origin server To the client, the proxy acts like a server To the server, the proxy acts like a client HTTP request Client Origin Server Proxy HTTP response Cox & Ng HTTP request HTTP response Networking 107 Why Proxies? Can perform useful functions as requests and responses pass through Examples: Caching, logging, anonymization Client A Request foo.html foo.html Request foo.html Client B Request foo.html Proxy cache foo.html Origin Server Slower more expensive global network foo.html Fast inexpensive local network Cox & Ng Networking 108 For More Information Study the Tiny Web server described in your text Tiny is a sequential Web server Serves static and dynamic content to real browsers • text files, HTML files, GIF and JPEG images 220 lines of commented C code Also comes with an implementation of the CGI script for the add.com addition portal Cox & Ng Networking 109 Next Time Concurrency Cox & Ng Networking 110
