1 / 40

Implementing Manager-Worker Programs in MPI

Learn how to implement manager-worker programs and explore parallel algorithms for document classification and clustering. Topics include creating communicators, non-blocking communications, and pipelining tasks.

beverlyhill
Download Presentation

Implementing Manager-Worker Programs in MPI

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. CS668 Lecture 9 Objectives • Material from Chapter 9 • Show how to implement manager-worker programs • Parallel Algorithms for Document Classification • Parallel Algorithms for Clustering

  2. Outline • Creating communicators • Non-blocking communications • Implementation • Pipelining Tasks • Clustering Vectors

  3. Implementation of a Very Simple Document Classifier • Manager/Worker Design Strategy • Manager description • create initial tasks • communicate to/from workers • Worker description • receive tasks • Alternate between task-computation and communication with master

  4. Structure of Main program:Manager/Worker Paradigm MPI_Init (&argc, &argv); // what is my rank? MPI_Comm_rank(MPI_COMM_WORLD, &myrank); // how many processors are there? MPI_Comm_size(MPI_COMM_WORLD, &p); if (myid == 0) Manager(p); else Worker(myid, p); MPI_Barrier(MPI_COMM_WORLD); MPI_Finalize(); return(0);

  5. More MPI functions • MPI_Abort • MPI_Comm_split • MPI_Isend, MPI_Irecv, MPI_Wait • MPI_Probe • MPI_Get_count • MPI_Testsome

  6. MPI_Abort • A “quick and dirty” way for one process to terminate all processes in a specified communicator • Example use: If manager cannot allocate memory needed to store document profile vectors int MPI_Abort ( MPI_Comm comm, /* Communicator */ int error_code)/* Value returned to calling environment */

  7. Creating a Workers-only Communicator • To support workers-only broadcast, need workers-only communicator • Can use MPI_Comm_split • Excluded processes (e.g., Manager) passes MPI_UNDEFINED as the value of split_key, meaning it will not be part of any new communicator

  8. Workers-only Communicator int id; MPI_Comm worker_comm; ... if (!id) /* Manager */ MPI_Comm_split (MPI_COMM_WORLD, MPI_UNDEFINED, id, &worker_comm); else /* Worker */ MPI_Comm_split (MPI_COMM_WORLD, 0, id, &worker_comm);

  9. Nonblocking Send / Receive • Persistent communications reduce overhead when repeated calls to same point-to-point message passing routines • MPI_Isend, MPI_Irecv initiate operation • MPI_Wait blocks until operation complete • Calls can be made early • MPI_Isend as soon as value(s) assigned • MPI_Irecv as soon as buffer available • Can eliminate a message copying step • Allows communication / computation overlap

  10. Pointer to object that identifies communication operation Function MPI_Isend int MPI_Isend ( void *buffer, int cnt, MPI_Datatype dtype, int dest, int tag, MPI_Comm comm, MPI_Request *handle )

  11. Pointer to object that identifies communication operation Function MPI_Irecv int MPI_Irecv ( void *buffer, int cnt, MPI_Datatype dtype, int src, int tag, MPI_Comm comm, MPI_Request *handle )

  12. Function MPI_Wait int MPI_Wait ( MPI_Request *handle, MPI_Status *status ) Blocks until operation associated with pointer handle completes. status points to object containing info on received message

  13. Receiving Problem • Worker does not know length of message it will receive • Example, the length of File Path Name • Alternatives • Allocate huge buffer • Check length of incoming message, then allocate buffer • We’ll take the second alternative

  14. Function MPI_Probe int MPI_Probe ( int src, int tag, MPI_Comm comm, MPI_Status *status ) Works for any Send. Blocks until message is available to be received from process with rank src with message tag tag; status pointer gives info on message size.

  15. Function MPI_Get_count int MPI_Get_count ( MPI_Status *status, MPI_Datatype dtype, int *cnt ) cnt returns the number of elements in message

  16. MPI_Testsome • Non-blocking test • Often need to check whether one or more messages have arrived • Manager posts a nonblocking receive to each worker process • Builds an array of handles or request objects • Testsome allows manager to determine how many messages have arrived

  17. Function MPI_Testsome int MPI_Testsome ( int in_cnt, /* IN - Number of nonblocking receives to check */ MPI_Request *handlearray, /* IN - Handles of pending receives */ int *out_cnt, /* OUT - Number of completed communications */ int *index_array, /* OUT - Indices of completed communications */ MPI_Status *status_array) /* OUT - Status records for completed comms */

  18. Document Classification Problem • Search directories, subdirectories for documents (look for .html, .txt, .tex, etc.) • Using a dictionary of key words, create a profile vector for each document • Store profile vectors

  19. Data Dependence Graph (1)

  20. Partitioning and Communication • Most time spent reading documents and generating profile vectors • Create two primitive tasks for each document

  21. Data Dependence Graph (2)

  22. Agglomeration and Mapping • Number of tasks not known at compile time • Tasks do not communicate with each other • Time needed to perform tasks varies widely • Strategy: map tasks to processes at run time

  23. Manager/worker-style Algorithm • Task/Functional Partitioning • Domain/Data Partitioning

  24. Roles of Manager and Workers

  25. Manager Pseudocode Identify documents Receive dictionary size from worker 0 Allocate matrix to store document vectors repeat Receive message from worker if message contains document vector Store document vector endif if documents remain then Send worker file name else Send worker termination message endif until all workers terminated Write document vectors to file

  26. Worker Pseudocode Send first request for work to manager if worker 0 then Read dictionary from file endif Broadcast dictionary among workers Build hash table from dictionary if worker 0 then Send dictionary size to manager endif repeat Receive file name from manager if file name is NULL then terminate endif Read document, generate document vector Send document vector to manager forever

  27. Task/Channel Graph

  28. Enhancements • Finding middle ground between pre-allocation and one-at-a-time allocation of file paths • Pipelining of document processing

  29. Load imbalance n/p Allocation Alternatives Time Excessive communication overhead 1 Documents Allocated per Request

  30. Pipelining

  31. Time Savings through Pipelining

  32. Pipelined Manager Pseudocode a 0 {assigned jobs} j  0 {available jobs} w  0 {workers waiting for assignment} repeat if (j > 0) and (w > 0) then assign job to worker j  j– 1; w  w– 1; a  a + 1 elseif (j > 0) then handle an incoming message from workers increment w else get another job increment j endif until (a = n) and (w = p)

  33. Summary • Manager/worker paradigm • Dynamic number of tasks • Variable task lengths • No communications between tasks • New tools for “kit” • Create manager/worker program • Create workers-only communicator • Non-blocking send/receive • Testing for completed communications • Next Step: Cluster Profile Vectors

  34. K-Means Clustering • Assumes documents are real-valued vectors. • Assumes distance function on vector pairs • Clusters based on centroids (aka the center of gravity or mean) of points in a cluster, c: • Reassignment of instances to clusters is based on distance of vector to the current cluster centroids. • (Or one can equivalently phrase it in terms of similarities)

  35. K-Means Algorithm Let d be the distance measure between instances. Select k random instances {s1, s2,… sk} as seeds. Until clustering converges or other stopping criterion: For each instance xi: Assign xi to the cluster cjsuch that d(xi, sj) is minimal. // Now Update the seeds to the centroid of each cluster) For each cluster cj sj = (cj)

  36. Pick seeds Reassign clusters Compute centroids Reassign clusters x x x Compute centroids x x x K Means Example(K=2) Reassign clusters Converged!

  37. Termination conditions • Desire that docs in a cluster are unchanged • Several possibilities, e.g., • A fixed number of iterations. • Doc partition unchanged. • Centroid positions don’t change. • We’ll choose termination when only small fraction change (threshold value)

  38. Quiz: • Describe Manager/Worker pseudo-code that implements the K-means algorithm in parallel • What data partitioning for parallelism? • How are cluster centers updated and distributed?

  39. Hints • objects to be clustered are evenly partitioned among all processes • cluster centers are replicated • Global-sum reduction on cluster centers is performed at the end of each iteration to generate the new cluster centers. • Use MPI_Bcast and MPI_Allreduce

More Related