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CPS110: More Networks

CPS110: More Networks. Landon Cox March 30, 2009. Virtual/physical interfaces. Applications. Reliable messages. Unreliable messages. Byte streams. Distinct messages. Ordered messages. Unordered messages. OS. Hardware. Ordered messages. Networks can re-order IP messages

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CPS110: More Networks

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  1. CPS110: More Networks Landon Cox March 30, 2009

  2. Virtual/physical interfaces Applications Reliable messages Unreliable messages Byte streams Distinct messages Ordered messages Unordered messages OS Hardware

  3. Ordered messages • Networks can re-order IP messages • E.g. Send: A, B. Arrive: B, A • How should we fix this? • Assign sequence numbers (0, 1, 2, 3, 4, …)

  4. Ordered messages • Do what for a message that arrives out of order? • (0, 1, 3, 2, 4) • Save #3 and deliver after #2 is delivered • (this is what TCP does) • Drop #3, deliver #2, deliver #4 • Deliver #3, drop #2, deliver #4 b. and c. are ordered, but not reliable (messages are dropped). Relies on the reliability layer to handle lost messages.

  5. Ordered messages • For a notion of order, first need “connections” • Why? • Must know which messages are related to each other • Idea in TCP • Open a connection • Send a sequence of messages • Close the connection • Opening a connection ties two sockets together • Connection is socket-to-socket unique: only these sockets can use it • Sequence numbers are connection specific

  6. Virtual/physical interfaces Applications Reliable messages Unreliable messages Byte streams Distinct messages Ordered messages Unordered messages OS Hardware

  7. Reliable messages • Usually paired with ordering • TCP provides both ordering and reliability • Hardware interface • Network drops messages • Network duplicates messages • Network corrupts messages • Application interface • Every message is delivered exactly once

  8. Detecting and fixing drops • How to fix a dropped message? • Have sender re-send it • How does sender know it’s been dropped? • Have receiver tell the sender • Receiver may not know it’s been sent • Like asking in the car, • “If we left you at the theater, speak up.”

  9. Detecting and fixing drops • Have receiver acknowledge each message • Called an “ACK” • If sender doesn’t get an ACK • Assume message has been dropped • Resend original message • Is this ok for the sender to assume? • No. ACKs can be dropped too (or delayed)

  10. Detecting and fixing drops • Possible outcomes • Message is delayed or dropped • ACK is delayed or dropped • Strategy • Deal with all as though message was dropped • Worst case if message wasn’t dropped after all? • Need to deal with duplicate messages • How to detect and fix duplicate messages? • Easy. Just use the sequence number and drop duplicate.

  11. What about corruption? • Messages can also be corrupted • Bits get flipped, etc • Especially true over wireless networks • How to deal with this? • Add a checksum (a little redundancy) • Checksum usually = sum of all bits • Drop corrupted messages

  12. What about corruption? • Dropping corrupted messages is elegant • Transforms problem into a dropped message • We already know how to deal with drops • Common technique • Solve one problem by transforming it into another • Corruption  drops • Drops  duplicates • Drop any duplicate messages (very simple)

  13. Virtual/physical interfaces Applications Reliable messages Unreliable messages Byte streams Distinct messages Ordered messages Unordered messages OS Hardware

  14. Byte streams • Hardware interface • Send information in discrete messages • Application interface • Send data in a continuous stream • Like reading/writing from/to a file

  15. Byte streams • Many apps think about info in distinct messages • What if you want to send more data than fits? • UDP max message size is 64 KB • What if data never ends? • Streamed media • TCP provides “byte streams” instead of messages

  16. Byte streams • Sender writes messages of arbitrary size • TCP breaks up the stream into fragments • Reassembles the fragments at destination • Receiver sees a byte stream • Fragments are not visible to either process • Programming the receiver • Must loop until certain number of bytes arrive • Otherwise, might get first fragment and return

  17. Byte streams • UDP makes boundaries visible • TCP makes boundaries invisible • (loop until you get everything you need) • How to know # of bytes to receive? • Size is contained in header • Read until you see a pattern (sentinel) • Sender closes connection

  18. Sentinels • Idea: message is done when special pattern arrives • Example: C strings • How do we know the end of a C string? • When you reach the null-termination character (‘\0’) • Ok, now say we are sending an arbitrary file • Can we use ‘\0’ as a sentinel? • No. The data payload may contain ‘\0’ chars • What can we do then?

  19. Course administration • Last day for Project 2 submissions • 89, 89, 89, 89, 87, 86, 83, 79, 79, 78, 76, 75, 49, 33, 28 • Project 3 will be out next week • Hack into a server • Socket programming how-to posted • Ryan will cover in discussion section this week • Will post example client/server code • Any questions?

  20. Distributed systems You use distributed systems everyday. Both on your PC and behind the scenes.

  21. Motivation for distributed apps • Performance

  22. Motivation for distributed apps • Performance • Co-location • Can locate computer near local resources • Examples of local resources • People, sensors, sensitive database

  23. Motivation for distributed apps • Performance • Co-location • Reliability • Not all computers will go down at once • Due to floods, fires, earthquakes, etc • Better chance of continuous service

  24. Motivation for distributed apps • Performance • Co-location • Reliability • Already have multiple machines • Can’t put everyone on one machine • Try to stitch existing machines together

  25. Building up to distributed apps • Needed two things in multi-threaded programs • Atomic primitives to control thread interleavings • (interrupt disable/enable, atomic test&set) • Way to share information between threads • (shared address space) • These won’t work for distributed applications • No interrupt disable/enable or atomic test&set • No shared memory

  26. Building up to distributed apps • Can only communicate through messages • Send messages • Receive messages • If no shared data, are there race conditions? • Sure, message might reflect an inconsistent state • Races can cause other problems too • Incorrect event ordering (fire missile after command) • Mutual exclusion (two people adding last spot in class)

  27. Send/receive primitives • So we need sharing and synchronization • Obvious we can use send/receive to share • Each message communicates information • Messages instead of load/store to shared memory • Can we use send/receive for synchronization? • Depends on the atomicity of our hardware primitives • “Try to build large atomic regions from small ones.”

  28. Send/receive primitives • Atomic operation provided by hardware • Can send a single Ethernet frame atomically • Ethernet detects simultaneous sends • Called a collision • Ethernet either allows one or none • A bigger problem in wireless networks (why?) • Idea: build up from atomic send X

  29. Send/receive primitives • Interleaved incoming packets • OS separates the packets • Forms whole messages from fragments • Passes messages up to various apps • How does OS know which packet goes to which app? • Port number in L4 (TCP, UDP, etc) header

  30. Send/receive primitives • Interleaved outgoing packets • OS ensures packets are whole • One app’s packets won’t change another’s • How does OS control access to the NIC? • Device driver “serializes” send requests • Use locks inside driver code

  31. Client-server • Many different distributed architectures • Client-server is the most common • Also called request-response • Basic interaction “GET /images/fish.gif HTTP/1.1”

  32. Client-server • Clients are machines you sit in front of • Send request to server • Wait for a response • Clients generally initiate communication • Writes are similar POST /cgi-bin/uploadfile.pl HTTP/1.1 Content-Type: application/x-www-form-urlencoded Content-Length: 49 filename=foo.txt&file+content=content+of+foo.txt

  33. Producer-consumer Soda drinker (consumer) Delivery person (producer) Vending machine (buffer)

  34. Producer-consumer • Have a server manage the coke machine • Clients can call two functions • client_produce () • client_consume () • Both send a request to the server • Both return when the request is done

  35. Producer-consumer client_produce () { send message to add coke wait for response } client_consume () { send message to get coke wait for response } server () { receive request (from any producer or consumer client) if (request is from a producer) { wait for empty spot in machine put coke in machine } else { wait for coke in machine take coke out of machine } send response } Anything missing? Need to wait for cokes/space.

  36. Producer-consumer client_produce () { send message to add coke wait for response } client_consume () { send message to get coke wait for response } server () { receive request (from any producer or consumer client) if (request is from a producer) { wait for empty spot in machine put coke in machine } else { wait for coke in machine take coke out of machine } send response } Does this work? No. Now we’ll deadlock.

  37. Producer-consumer client_produce () { send message to add coke wait for response } client_consume () { send message to get coke wait for response } server () { receive request (from any producer or consumer client) if (request is from a producer) { wait for empty spot in machine put coke in machine } else { wait for coke in machine take coke out of machine } send response } How do we solve this? Use threads at the server.

  38. Producer-consumer server () { while (1) { receive request (from any producer or consumer client) if (request is from a producer) { create a thread to handle the produce reqeust } else { create a thread to handle the consumer request } } } server_consume () { lock while (machine is empty) wait take coke from machine send response to client unlock } server_produce () { lock while (machine is full) wait put coke in machine send response to client unlock }

  39. Producer-consumer • Note how we used send/receive • Used to share information • (request/response messages) • Provides before/after constraint • (client waits for server) • Receive is like wait/down, send is like signal/up • Solution creates a thread per request • Can we lower the per-request overhead?

  40. Producer-consumer • Keep a pool of worker threads • When main loop gets a request • Pass request to an existing worker thread • When worker thread is done • Wait for next request from dispatcher • Similar to disk scheduler in P1

  41. Other approaches • Don’t have to use worker threads • Just want slow operations to run in parallel • What are the slow operations? • Producing/consuming a coke • Receiving a network request

  42. Other approaches • Want server to work while waiting for requests • Could poll (using the select() system call) • Instead of blocking in recv() • Poll to see if there is a new message, call recv() if there is • Also must avoid calling wait() if there is no coke/space • Could use signals (SIGIO) • Incoming network messages generate a signal • The signal interrupts the thread blocked in wait() • Threads are a much easier solution!

  43. Network abstractions • We’ve been using send/receive • Client sends a request to the server • Server receives request • Server sends response to client • What else in CS is this interaction like? • Calling a function

  44. Remote procedure call (RPC) • RPC makes request/response look local • Provide a function call abstraction • RPC isn’t a really a function call • In a normal call, the PC jumps to the function • Function then jumps back to caller • This is similar to request/response though • Stream of control goes from client to server • And then returns back to the client

  45. The RPC illusion • How to make send/recv look like a function call? • Client wants • Send to server to look like calling a function • Reply from server to look like function returning • Server wants • Receive from client to look like a function being called • Wants to send response like returning from function

  46. RPC stub functions • Key to making RPC work • Stub functions

  47. RPC stub functions call send Client stub recv return send return Server stub call recv

  48. RPC stub functions • Client stub 1) Builds request message with server function name and parameters 2) Sends request message to server stub • (transfer control to server stub) 8) Receives response message from server stub 9) Returns response value to client • Server stub 3) Receives request message 4) Calls the right server function with the specified parameters 5) Waits for the server function to return 6) Builds a response message with the return value 7) Sends response message to client stub

  49. RPC notes • Client makes a normal function call • Can’t tell that it’s to a remote server (sort of) • Server function is called like a normal function • Can’t tell that it’s returning to a remote client • Control returns to client as from a function • Common technique to add functionality • Leaving existing component interfaces in-place • Implement both sides between existing layers

  50. RPC example • Client calls produce(5) Client stub: Server stub: // must be named produce! int produce (int n) { int status; send (sock, &n, sizeof(n)); recv (sock, &status, sizeof(status)); return status; } // could be named anything void produce_stub () { int n; int status; recv (sock, &n, sizeof(n)); // produce func on server! status = produce (n); send (sock, &status, sizeof(status)); } Server stub code can be generated automatically (C/C++: rpcgen, Java: rmic) What info do you need to generate the stubs? Input parameter types and the return value type.

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