1 / 22

Basic Networking

Basic Networking. Vivek Pai Nov 26, 2002. Communication. You’ve already seen some of it Web server project(s) Machines have “names” Human-readable names are convenience “Actual” name is IP (Internet Protocol) address For example, 127.0.0.1 means “this machine”

Jimmy
Télécharger la présentation

Basic Networking

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Basic Networking Vivek Pai Nov 26, 2002

  2. Communication • You’ve already seen some of it • Web server project(s) • Machines have “names” • Human-readable names are convenience • “Actual” name is IP (Internet Protocol) address • For example, 127.0.0.1 means “this machine” • nslookup www.cs.princeton.edu gives 128.112.136.11

  3. Names & Services • Multiple protocols • ssh, ftp, telnet, http, etc. • How do we know how to connect? • Machines also have port numbers • 16 bit quantity (0-65535) • Protocols have default port # • Can still do “telnet 128.112.136.11 80”

  4. But The Web Is Massive • Possible names >> possible IP addresses • World population > possible IP addresses • Many names map to same IP addr • Use extra information to disambiguate • In HTTP, request contains “Host: name” header • Many connections to same (machine, port #) • Use (src addr, src port, dst addr, dst port) to identify connection

  5. Measuring Latency • Here to Berkeley, CA • Mapquest: 2898 miles (47 hours driving) • Speed of light: 186000 miles/sec • 15.6 ms (slightly slower than a disk access) • Ping: www.cs.berkeley.edu • 84ms round trip (less than 3x slower) • Why? Packet switching

  6. Circuit Switching versus Packet Switching • Circuit – reserve resources in advance • Hold resources for entire communication • Example: phone line • Packet – break data into small pieces • Pieces identify themselves, “share” links • Individual pieces routed to destination • Example: internet • Problem: no guarantee pieces reach

  7. Mapping Packet Switching % traceroute www.cs.berkeley.edu traceroute to hyperion.cs.berkeley.edu (169.229.60.105), 64 hops max, 40 byte packets 1 * * * 2 csgate.CS.Princeton.EDU (128.112.152.1) 5.847 ms 5.718 ms 5.652 ms 3 vgate1.Princeton.EDU (128.112.128.114) 5.400 ms 5.371 ms 5.306 ms 4 local.princeton.magpi.net (198.32.42.65) 6.873 ms 8.128 ms 6.597 ms 5 remote1.abilene.magpi.net (198.32.42.210) 9.515 ms 9.628 ms 10.071 ms 6 nycmng-washng.abilene.ucaid.edu (198.32.8.84) 14.259 ms 15.520 ms 14.007 ms 7 chinng-nycmng.abilene.ucaid.edu (198.32.8.82) 34.292 ms 34.326 ms 34.271 ms 8 iplsng-chinng.abilene.ucaid.edu (198.32.8.77) 50.394 ms 56.998 ms 46.205 ms 9 kscyng-iplsng.abilene.ucaid.edu (198.32.8.81) 47.535 ms 46.830 ms 61.605 ms 10 snvang-kscyng.abilene.ucaid.edu (198.32.8.102) 82.091 ms 82.941 ms 83.235 ms 11 snva-snvang.abilene.ucaid.edu (198.32.11.122) 82.910 ms 82.601 ms 81.987 ms 12 198.32.249.161 (198.32.249.161) 82.314 ms 82.394 ms 82.182 ms 13 BERK--SUNV.POS.calren2.net (198.32.249.13) 83.827 ms 84.060 ms 83.462 ms 14 pos1-0.inr-000-eva.Berkeley.EDU (128.32.0.89) 83.707 ms 83.579 ms 83.702 ms 15 vlan199.inr-202-doecev.Berkeley.EDU (128.32.0.203) 83.986 ms 148.940 ms 84.031 ms 16 doecev-soda-br-6-4.EECS.Berkeley.EDU (128.32.255.170) 84.365 ms 84.410 ms 84.167 ms 17 hyperion.CS.Berkeley.EDU (169.229.60.105) 84.506 ms 84.017 ms 84.393 ms

  8. Abilene (Internet2) Nodes

  9. Failure Behavior • What happens if • We send the packet • It reaches Sunnyvale • It meanders to Berkeley • Web server loses power • Can we avoid this situation?

  10. The “End To End” Argument • Don’t rely on lower layers of the system to ensure something happens • If it needs to occur, build the logic into the endpoints • Implications: • Intermediate components simplified • Repetition possible at endpoints (use OS) • What is reliability?

  11. Do Applications Care? • Some do • Most don’t • Use whatever OS provides • Good enough for most purposes • What do applications want? • Performance • Simplicity

  12. Reading & Writing • A file: • Is made into a “descriptor” via some call • Is an unstructured stream of bytes • Can be read/written • OS provides low-level interaction • Applications use read/write calls • Sounds workable?

  13. Kernel Internals int read(struct proc *p, struct read_args *uap) { register struct file *fp; int error; if ((fp = holdfp(p->p_fd, uap->fd, FREAD)) == NULL) return (EBADF); error = dofileread(p, fp, uap->fd, uap->buf, uap->nbyte, (off_t)-1, 0); fdrop(fp, p); return(error); }

  14. Kernel Internals int dofileread(struct proc *p, struct file *fp, int fd, flags, void *buf, size_t nbyte, off_t offset) { […] (elided some code here) cnt = nbyte; if ((error = fo_read(fp, &auio, fp->f_cred, flags, p))) { if (auio.uio_resid != cnt && (error == ERESTART || error == EINTR || error == EWOULDBLOCK)) error = 0; } cnt -= auio.uio_resid; p->p_retval[0] = cnt; return (error); }

  15. Kernel Internals static __inline int fo_read(struct file *fp, struct uio *uio, struct ucred *cred, struct proc *p, int flags) { int error; fhold(fp); error = (*fp->f_ops->fo_read)(fp, uio, cred, flags, p); fdrop(fp, p); return (error); }

  16. Who Are These People

  17. Gary Kildall • Founded Intergalactic Digital Research • Wrote CP/M • Fairly portable • Wide use before IBM PC • Sales of $5.1M in 1981 • Almost became PC’s OS • Died in 1994 from head injuries

  18. Network Connections As FDs • Network connection usually called “socket” • Interesting new system calls • socket( ) – creates an fd for networking use • connect( ) – connects to the specified machine • bind( ) – specifies port # for this socket • listen( ) – waits for incoming connections • accept( ) – gets connection from other machine • And, of course, read( ) and write( )

  19. New Semantics • Doing a write( ) • What’s the latency/bandwidth of a disk? • When does a write( ) “complete”? • Where did data actually go before? • Can we do something similar now? • What about read( ) • Is a disk read different from a network read? • When should a read return? • What should a read return?

  20. Buffering • Provided by OS • Memory on both sender and receiver sides • Sender: enables reliability, quick writes • Receiver: allows incoming data before read • Example – assume slow network • write(fd, buf, size); • memset(buf, 0, size) • write(fd, buf, size);

  21. Interprocess Communications • Shared memory • Threads sharing address space • Processes memory-mapping the same file • Processes using shared memory system calls • Sockets and read/write • Nothing prohibits connection to same machine • Even faster mechanism – different “domain” • Unix domain (local) versus Internet (either)

  22. Sockets vs Shared Memory • Sockets • Higher overhead • No common parent/file needed • “Active” operation – under program control • Shared memory • Locking due to synchronous operation • Fast reads/writes – no OS intervention • Harder to use multiple machines

More Related