Presentation is loading. Please wait.

Presentation is loading. Please wait.

Ipv4 Socket Address Structure struct in_addr { in_addr_t s_addr; /* 32-bit IPv4 address */ /* network byte ordered */ }; struct sockaddr_in { uint8_t sin_len;

Published byJosie Allan Modified over 9 years ago

Similar presentations

Presentation on theme: "Ipv4 Socket Address Structure struct in_addr { in_addr_t s_addr; /* 32-bit IPv4 address */ /* network byte ordered */ }; struct sockaddr_in { uint8_t sin_len;"— Presentation transcript:

1 Ipv4 Socket Address Structure struct in_addr { in_addr_t s_addr; /* 32-bit IPv4 address */ /* network byte ordered */ }; struct sockaddr_in { uint8_t sin_len; /* length of structure (16) */ sa_family_t sin_family; /* AF_INET */ in_port_t sin_port; /* 16-bit TCP/UDP port number */ /* network byte ordered */ struct in_addr sin_addr; /* 32-bit IPv4 address */ /*network byte ordered*/ char sin_zero[8]; /* unused */ }; data structure – not exchanged between hosts

2 struct in_addr { in_addr_t s_addr; /* 32-bit IPv4 address */ /* network byte ordered */ }; struct sockaddr_in { uint8_t sin_len; /* length of structure (16) */ sa_family_t sin_family; /* AF_INET */ in_port_t sin_port; /* 16-bit TCP/UDP port number */ /* network byte ordered */ struct in_addr sin_addr; /* 32-bit IPv4 address */ /*network byte ordered*/ char sin_zero[8]; /* unused */ }; Generic Socket Address Structure Passed as reference Prior to void definition

3 Generic Socket Address Structure int bind(int, struct sockaddr *, sock_len_t);

4 Ipv6 Socket Address Structure struct in6_addr { uint8_t s6_addr[16]; /* 128-bit IPv6 address */ /* network byte ordered */ }; #define SIN6_LEN /* required for compile-time tests */ struct sockaddr_in6 { uint8_t sin6_len; /* length of this struct (28) */ sa_family_t sin6_family; /* AF_INET6 */ in_port_t sin6_port; /* transport layer port# */ /* network byte ordered */ uint32_t sin6_flowinfo; /* flow information, undefined */ struct in6_addr sin6_addr; /* IPv6 address */ /* network byte ordered */ uint32_t sin6_scope_id; /* set of interfaces for a scope */ };

5 Value-Results arguments bind, connect, sento

6 Value-Result arguments Kernel to the process, size can change accept, recvfrom, getsockname, getpeername Fixed size data structure Kernel informs how much information was stored

7 Socket Address Structures

8 Byte ordering functions

9 Internet Protocols Network byte order → big-endian  TCP Port: 16 bits  Ipv4 address: 32 bits # include uint16_t htons(uint16_t host16bitvalue) ; uint32_t htonl(uint32_t host32bitvalue) ; Both return: value in network byte order uint16_t ntohs(uint16_t net16bitvalue) ; uint32_t ntohl(uint32_t net32bitvalue) ; Both return: value in host byte order

10 Byte manipulation function Operates on multibyte fileds, without interpreting the data, and without asuming that the data is a null-terminated C string bzero, bcopy, bcmp memset, memcpy, memcmp

11 Address convertion function Converts an ASCII string into network byte ordered binary values #include int inet_aton(const char *strptr, struct in_addr *addrptr); Returns: 1 if string was valid, 0 on error in_addr_t inet_addr(const char *strptr); Returns: 32-bit binary network byte ordered IPv4 address; INADDR_NONE if error char *inet_ntoa(struct in_addr inaddr); Returns: pointer to dotted-decimal string

12 Address convertion function

13 read, write It may read/write less than needed due to finite buffer → call function Only if write is nonblocking

14 read, write lib/readn.c 1 #include "unp.h" 2 ssize_t /* Read "n" bytes from a descriptor. */ 3 readn(int fd, void *vptr, size_t n) 4 { 5 size_t nleft; 6 ssize_t nread; 7 char *ptr; 8 ptr = vptr; 9 nleft = n; 10 while (nleft > 0) { 11 if ( (nread = read(fd, ptr, nleft)) < 0) { 12 if (errno == EINTR) 13 nread = 0; /* and call read() again */ 14 else 15 return (-1); 16 } else if (nread == 0) 17 break; /* EOF */ 18 nleft -= nread; 19 ptr += nread; 20 } 21 return (n - nleft); /* return >= 0 */ 22 }

15 read, write lib/writen.c 1 #include "unp.h" 2 ssize_t /* Write "n" bytes to a descriptor. */ 3 writen(int fd, const void *vptr, size_t n) 4 { 5size_t nleft; 6 ssize_t nwritten; 7 const char *ptr; 8 ptr = vptr; 9 nleft = n; 10 while (nleft > 0) { 11 if ( (nwritten = write(fd, ptr, nleft)) <= 0) { 12 if (nwritten < 0 && errno == EINTR) 13 nwritten = 0; /* and call write() again */ 14 else 15 return (-1);/* error */ 16 } 17 nleft -= nwritten; 18 ptr += nwritten; 19 } 20 return (n); 21 }

16 read, write 1 # include "unp.h" 2 static int read_cnt; 3 static char *read_ptr; 4 static char read_buf[MAXLINE]; 5 static ssize_t 6 my_read(int fd, char *ptr) 7 { 8 if (read_cnt <= 0) { 9 again: 10 if ( (read_cnt = read(fd, read_buf, sizeof(read_buf))) < 0) { 11 if (errno == EINTR) 12 goto again; 13 return (-1); 14 } else if (read_cnt == 0) 15 return (0); 16 read_ptr = read_buf; 17 } 18 read_cnt--; 19 *ptr = *read_ptr++; 20 return (1); 21 }

17 22 ssize_t 23 readline(int fd, void *vptr, size_t maxlen) 24 { 25 ssize_t n, rc; 26 char c, *ptr; 27 ptr = vptr; 28 for (n = 1; n < maxlen; n++) { 29 if ( (rc = my_read(fd, &c)) == 1) { 30 *ptr++ = c; 31 if (c == '\n') 32 break; /* newline is stored, like fgets() */ 33 } else if (rc == 0) { 34 *ptr = 0; 35 return (n - 1); /* EOF, n - 1 bytes were read */ 36 } else 37 return (-1); /* error, errno set by read() */ 38 } 39 *ptr = 0; /* null terminate like fgets() */ 40 return (n); 41 } 42 ssize_t 43 readlinebuf(void **vptrptr) 44 { 45 if (read_cnt) 46 *vptrptr = read_ptr; 47 return (read_cnt); 48 } read, write

18 isfdtype It checks whether the descriptor is a socket descriptor

19 Socket functions for elementary TCP client-server

20 The socket API Function socket int socket ( int family, int type, int protocol) return > 0 if OK, -1 if error Returns socket descriptor (small positive integer), similar to UNIX file descriptor, to be used perform functions on the socket such as read, write and close

21 socket #include int socket (int family, int type, int protocol); Returns: non-negative descriptor if OK, -1 on error

22 Socket Function Parameters: family: specifies the protocol family: AF_INET – for IPv4 AF_INET6 – for IPv6 AF_UNIX ou AF_LOCAL- Unix domain socket type : specifies transport protocol: SOCK_STREAM: stream socket for TCP SOCK_DGRAM: datagram socket for UDP protocol : usually set to zero

23 Combination of interest Family Type AF_INETSOCK_STREAMSOCK_DGRAM AF_UNIXSOCK_STREAMSOCK_DGRAM Exemple: sockfd = socket(AF_INET, SOCK_STREAM, 0), creates an IPv4 socket to be used by TCP socket Function

24 int connect ( int sockfd, const struct sockaddr *servaddr, int addrlen) return 0 if OK, -1 if error, Used for establishing a connection:three-way handshake sockfd : return parameter of socket() servaddr : data structure initiated with remote socket identifications (remote IP address, remote port number) For a client TCP, it is not necessary to perform bind: the kernel chooses the local port ephemeral port number and the source IP number if necessary Chosen in a way to avoid conflict of use of port number Connect Function

25 connect errors  timeout – erro ETIMEDOUT, 75 seconds, configurable  If the answer to a SYN segment is an RST one – error ECONNREFUSED – no process listening to the port  Destination unreachable (ICMP), soft error, tries for 75 seconds (4.4 BSD) #include int connect(int sockfd, const struct sockaddr *servaddr, socklen_t addrlen); Returns: 0 if OK, -1 on error

26 int bind(int sockfd, (struct sockaddr)* myaddr, int socklen) return 0 if OK, -1 if error  bind a local protocol address given by the structure myaddr to a socket ( sockfd)  The application can let the kernel chooses the IP address and the port number; Bind Function

27 If a host has more than one IP, then the kernel can choose one Ephemeral port numbers are chosen to avoid conflict with other socket To let the kernel chooses the IP address the constant INADDR_ANY should be assigned to the IP address myaddr To let the kernel chooses an ephemeral port number the constant zero should be set to the corresponding field of myaddr: *myaddr.sin_port = 0; *myaddr.sin_addr.s_addr = INADDR_ANY

28 bind Bind performed by TCP server restricts the socket to receiving incoming client connection destined only to that IP address #include int bind (int sockfd, const struct sockaddr *myaddr, socklen_t addrlen); Returns: 0 if OK, -1 on error

29 bind No cliente, kernel faz o bind com o endereço IP da interface

30 Listen Function An active (client) socket is one that called connect com o socket, starting a 3-way handshake with a remote host; An applications (server) which calls listen, makes an unconnected socket a passive one meaning that the kernel must accept incoming connection requests directed to this socket. CLOSED → LISTEN Clients call connect while servers call listen followed by accept The backlog parameter indicates the total size of two queues: the complete queue (ESTABLISHED state) and the incomplete connection queue (SYN_RVCD state) int listen (int sockfd, (struct sockaddr) * myaddr, int backlog) return 0 if OK, -1 if error

31 listen

32

33

34

35 accept Function Called by a TCP server to return the next completed connection from the front of the completed connection queue. If the queue is empty the process is oput to sleep int accept (int sockfd, (struct sockaddr) * cliaddr, int * socklen) returns nonnegative descriptor if OK, -1 if error  aadrlen is a value-result argument and it returns the size of the structure pointed to by cliaddr, i.e., the number of bytes stored by the kernel in the socket address structure.

36 fork - exec Fork is called once but it returns twice. The return value tell the process whether it is a parent or a child It returns once to the calling process (parent) with a return value that is the process ID of the newly created process (child) It returns once in the child, with a return value of zero (0) All the descriptors opened by the parent before the fork are shared with the child after the fork. connected sockts aer an accept and a fork is shared with the Two uses of fork: a process makes a copy of itself (fork) and a process executes another program ( fork e exec ) # include pid_t fork(void); Returns: 0 in child, process ID of child in parent, -1 on error

37 fork - exec #include int execl (const char *pathname, const char *arg0,... /* (char *) 0 */ ); int execv (const char *pathname, char *const argv[ ]); int execle (const char *pathname, const char *arg0,... /* (char *) 0, char *const envp[ ] */ ); int execve (const char *pathname, char *const argv[ ], char *const envp[ ]); int execlp (const char *filename, const char *arg0,... /* (char *) 0 */ ); int execvp (const char *filename, char *const argv[ ]); All six return: -1 on error, no return on success

38 fork - exec

39 Concurrent server Concurrent server (iterative server) – one server, several connections. Concurrent server serves several active connections. Server performers a fork to create a child to handle the client request After accept, the server calls fork and the child serves the client (on connfd, the connected socket) and the parent waits for another connection (on listenfd, the listening socket)

40 Concurrent server Connect returns a brand new socket descriptor for the connection to be established with the TCP client. The return of a connect makes a socket a connected socket. On closing a socket only the specific connection (socket) is closed, the server remains listening to new socket connection request

41 Concurrent server A close performed by the server does not imply in terminating the connection, a FYN is sent only when the number of reference to the descriptor in the file table is zero – when a child is created the number of reference is incremented by one. If a server does not close the socket none of the children connections will be closed since the number of reference will never be zero and server runs out of descriptor

42 Concurrent server pid_t pid; int listenfd, connfd; listenfd = Socket(... ); /* fill in sockaddr_in{ } with server's well-known port */ Bind(listenfd,... ); Listen(listenfd, LISTENQ); for ( ; ; ) { connfd = Accept (listenfd,... ); /* probably blocks */ if( (pid = Fork()) == 0) { Close(listenfd); /* child closes listening socket */ doit(connfd); /* process the request */ Close(connfd); /* done with this client */ exit(0); /* child terminates */ } Close(connfd); /* parent closes connected socket */ }

43 Concurrent server

44

45

46 close SHUTDOWN used instead to force the termination of a connection #include int close (int sockfd); Returns: 0 if OK, -1 on error

47 getsockname and getpeername Returns the protocol address either local or remote usos:  connect not followed by bind  After calling bind with 0 srgument  TCP server performs a bind in a wildcard port #include int getsockname(int sockfd, struct sockaddr *localaddr, socklen_t *addrlen); int getpeername(int sockfd, struct sockaddr *peeraddr, socklen_t *addrlen); Returns: 0 if OK, -1 on error

48 getsocketname and getpeername lib/sockfd_to_family.c 1 #include "unp.h" 2 int 3 sockfd_to_family(int sockfd) 4 { 5 struct sockaddr_storage ss; 6 socklen_t len; 7 len = sizeof(ss); 8 if (getsockname(sockfd, (SA *) &ss, &len) < 0) 9 return (-1); 10 return (ss.ss_family); 11 }

49 TCP ports and concurrent servers multihomed – one-or-any any-wildcard

50 TCP ports and concurrent servers

Download ppt "Ipv4 Socket Address Structure struct in_addr { in_addr_t s_addr; /* 32-bit IPv4 address */ /* network byte ordered */ }; struct sockaddr_in { uint8_t sin_len;"

Similar presentations

Network Programming Week #1 J.P. Yoo

Network Programming Week #1 J.P. Yoo
Socket Programming 15-441 Computer Networks, Spring 2008 Your TAs.

Socket Programming Computer Networks, Spring 2008 Your TAs.
Echo server The client reads a line of text from its standard input and writes the line to the server The server reads the line from its network input.

Echo server The client reads a line of text from its standard input and writes the line to the server The server reads the line from its network input.
Socket Programming 101 Vivek Ramachandran.

Socket Programming 101 Vivek Ramachandran.
Introduction to Sockets Jan 2005. Why do we need sockets? Provides an abstraction for interprocess communication.

Introduction to Sockets Jan Why do we need sockets? Provides an abstraction for interprocess communication.
Socket Programming CS3320 Fall 2010.

Socket Programming CS3320 Fall 2010.
MERANCANG Program Transfer File (PTF) PTFServer dan PTFClient I Made Astawa

MERANCANG Program Transfer File (PTF) PTFServer dan PTFClient I Made Astawa
IPv6 Technologies and Advanced Services page 1 Porting applications to IPv6 OpenH323 and IPv6 support K. Stamos Computer Engineer, University of Patras.

IPv6 Technologies and Advanced Services page 1 Porting applications to IPv6 OpenH323 and IPv6 support K. Stamos Computer Engineer, University of Patras.
CSE 333 – SECTION 8 Networking and sockets. Overview Network Sockets IP addresses and IP address structures in C/C++ DNS – Resolving DNS names Demos.

CSE 333 – SECTION 8 Networking and sockets. Overview Network Sockets IP addresses and IP address structures in C/C++ DNS – Resolving DNS names Demos.
Taekyung Kim 0x410 ~ 0x430 2014. 11. 20. 2 3 International Standards Organization (ISO) is a multinational body dedicated to worldwide agreement on international.

Taekyung Kim 0x410 ~ 0x International Standards Organization (ISO) is a multinational body dedicated to worldwide agreement on international.
Programming with UDP – I Covered Subjects: IPv4 Socket Address Structure Byte Ordering Functions Address Access/Conversion Functions Functions: 1.socket()

Programming with UDP – I Covered Subjects: IPv4 Socket Address Structure Byte Ordering Functions Address Access/Conversion Functions Functions: 1.socket()
CS252: Systems Programming Ninghui Li Based on slides by Prof. Gustavo Rodriguez-Rivera Topic 16: Socket Programming & Project 5.

CS252: Systems Programming Ninghui Li Based on slides by Prof. Gustavo Rodriguez-Rivera Topic 16: Socket Programming & Project 5.
Elementary TCP Sockets Computer Networks Computer Networks Term B10 UNIX Network Programming Vol. 1, Second Ed. Stevens Chapter 4.

Elementary TCP Sockets Computer Networks Computer Networks Term B10 UNIX Network Programming Vol. 1, Second Ed. Stevens Chapter 4.
Networks: TCP/IP Socket Calls1 Elementary TCP Sockets Chapter 4 UNIX Network Programming Vol. 1, Second Ed. Stevens.

Networks: TCP/IP Socket Calls1 Elementary TCP Sockets Chapter 4 UNIX Network Programming Vol. 1, Second Ed. Stevens.
Elementary TCP Sockets Chapter 4 UNIX Network Programming Vol. 1, Second Ed. Stevens.

Elementary TCP Sockets Chapter 4 UNIX Network Programming Vol. 1, Second Ed. Stevens.
Sockets Programming Introduction © Dr. Ayman Abdel-Hamid, CS4254 Spring 20061 CS4254 Computer Network Architecture and Programming Dr. Ayman A. Abdel-Hamid.

Sockets Programming Introduction © Dr. Ayman Abdel-Hamid, CS4254 Spring CS4254 Computer Network Architecture and Programming Dr. Ayman A. Abdel-Hamid.
Tutorial 8 Socket Programming

Tutorial 8 Socket Programming
CS 311 – Lecture 19 Outline Internet Sockets – gethostname utility – struct hostent – inet_addr – Machine byte to Network byte order translation and vice.

CS 311 – Lecture 19 Outline Internet Sockets – gethostname utility – struct hostent – inet_addr – Machine byte to Network byte order translation and vice.
Programming with Berkeley Sockets Presented by Chris GauthierDickey Written by Daniel Stutzbach (I think!) for CIS 432/532 Useful References: ● man pages.

Programming with Berkeley Sockets Presented by Chris GauthierDickey Written by Daniel Stutzbach (I think!) for CIS 432/532 Useful References: ● man pages.
#include DatatypeDescription int8_t uint8_t int16_t uint16_t int32_t uint32_t Signed 8-bit integer Unsigned 8-bit integer Signed 16-bit integer Unsigned.

#include DatatypeDescription int8_t uint8_t int16_t uint16_t int32_t uint32_t Signed 8-bit integer Unsigned 8-bit integer Signed 16-bit integer Unsigned.

Similar presentations

Ads by Google