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One of my assignment is to implement RED/BLACK SOR algorithm using MPI. The grid is divided as checkboard and each iteration is split into two phases red and black. During each phase algorithm calculates either red or black non-boundary points of the grid. Rest of implementation is similar to as define in wiki.

Full Code: sequential here, parallel here.

Here is the sequential implementation

iteration = 0;
do {
    maxdiff = 0.0;
    for ( phase = 0; phase < 2 ; phase++){
        for ( i = 1 ; i < N-1 ; i++ ){
            for ( j = 1 + (even(i) ^ phase); j < N-1 ; j += 2 ){
                Gnew = stencil(G,i,j);
                diff = fabs(Gnew - G[i][j]);
                if ( diff > maxdiff )
                    maxdiff = diff;
                G[i][j] = G[i][j] + omega * (Gnew-G[i][j]);
            }
        }
    }
    iteration++;
} while (maxdiff > stopdiff);

For parallel implementation grid is first divided equally for different nodes (column wise). For example, if grid size is 8x8 and nodes 3, then we divide grid as 8x3, 8x3, 8x2 across those nodes. During communication data are exchanged to and from node's left and right neighbors. Figure below should give a clear picture of entire process.

/* Initializing MPI */
MPI_Init(&argc, &argv);
MPI_Comm_size(MPI_COMM_WORLD, &totalnodes);
MPI_Comm_rank(MPI_COMM_WORLD, &mynode);

// divide grid equally among different nodes
range(1, N - 1, totalnodes, mynode, &jsta, &jend);

// neigboring nodes
inext = mynode + 1;
iprev = mynode - 1;

iteration = 0;
do {
    maxdiff = 0.0;
    for ( phase = 0; phase < 2 ; phase++){

        // exchange column with neigboring node
        exchange(phase);

        for ( i = 1 ; i < N-1 ; i++ ){          // row

            for ( j = jsta + (even(i) ^ phase); j <= jend ; j += 2 ){   // column

                Gnew = stencil(G,i,j);
                diff = fabs(Gnew - G[i][j]);
                if ( diff > maxdiff )
                    maxdiff = diff;
                G[i][j] = G[i][j] + omega * (Gnew-G[i][j]);
            }
        }
    }

    MPI_Allreduce(&maxdiff, &diff, 1, MPI_DOUBLE, MPI_MAX, MPI_COMM_WORLD);
    maxdiff = diff;

    iteration++;
} while (maxdiff > stopdiff);

MPI_Barrier(MPI_COMM_WORLD);
MPI_Finalize();

Figure describes how grid is divided and neighbors communicate. Figure describes how grid is divided and neighbors communicate.

Problem is, final result of parallel and sequential SOR seem to vary by few bits. Need a fresh pair eye to skim through code to track this bug, I think communication between nodes are working alright.

$ cc -o sor-seq sor-seq.c -lm      
$ ./sor-seq 8 -print
    Running 8 x 8 SOR
    6.006      5.525      5.330      5.251      5.234      5.276      5.417      5.799 
    6.621      6.204      5.984      5.879      5.850      5.892      6.032      6.338 
    6.952      6.687      6.523      6.432      6.395      6.409      6.483      6.640 
    7.181      7.069      6.988      6.931      6.891      6.864      6.852      6.857 
    7.382      7.420      7.429      7.414      7.373      7.306      7.203      7.059 
    7.607      7.799      7.896      7.920      7.884      7.782      7.595      7.294 
    7.926      8.273      8.436      8.488      8.459      8.344      8.101      7.643 
    8.506      8.929      9.088      9.136      9.120      9.033      8.821      8.298 


$ mpicc -o sor-par sor-par.c   
$ mpirun -n 3 ./sor-seq 8 -print
    Running 8 x 8 SOR
    5.940      5.383      5.092      4.882      4.677      4.425      4.072      3.507
    6.496      5.939      5.542      5.201      4.839      4.392      3.794      2.950
    6.786      6.334      5.938      5.542      5.086      4.512      3.761      2.773
    6.994      6.672      6.334      5.942      5.450      4.809      3.964      2.873
    7.197      7.028      6.784      6.442      5.965      5.308      4.414      3.228
    7.445      7.457      7.335      7.075      6.660      6.045      5.157      3.896
    7.807      8.020      8.022      7.864      7.555      7.055      6.273      5.032
    8.443      8.795      8.868      8.805      8.640      8.348      7.848      6.920

    Node: 0
         5.940      5.383      5.092      4.882      0.000      0.000      0.000      0.000 
         6.496      5.939      5.542      5.201      0.000      0.000      0.000      0.000 
         6.786      6.334      5.938      5.542      0.000      0.000      0.000      0.000 
         6.994      6.672      6.334      5.942      0.000      0.000      0.000      0.000 
         7.197      7.028      6.784      6.442      0.000      0.000      0.000      0.000 
         7.445      7.457      7.335      7.075      0.000      0.000      0.000      0.000 
         7.807      8.020      8.022      7.864      0.000      0.000      0.000      0.000 
         8.443      8.795      8.868      8.805      0.000      0.000      0.000      0.000 

    Node: 1
         0.000      0.000      5.092      4.882      4.677      4.425      4.072      0.000 
         0.000      0.000      5.542      5.201      4.839      4.392      3.794      0.000 
         0.000      0.000      5.938      5.542      5.086      4.512      3.761      0.000 
         0.000      0.000      6.334      5.942      5.450      4.809      3.964      0.000 
         0.000      0.000      6.784      6.442      5.965      5.308      4.414      0.000 
         0.000      0.000      7.335      7.075      6.660      6.045      5.157      0.000 
         0.000      0.000      8.022      7.864      7.555      7.055      6.273      0.000 
         0.000      0.000      8.868      8.806      8.640      8.348      7.848      0.000 

    Node: 2
         0.000      0.000      0.000      0.000      0.000      4.425      4.072      3.507 
         0.000      0.000      0.000      0.000      0.000      4.392      3.794      2.950 
         0.000      0.000      0.000      0.000      0.000      4.512      3.761      2.773 
         0.000      0.000      0.000      0.000      0.000      4.809      3.964      2.873 
         0.000      0.000      0.000      0.000      0.000      5.308      4.414      3.228 
         0.000      0.000      0.000      0.000      0.000      6.045      5.157      3.896 
         0.000      0.000      0.000      0.000      0.000      7.055      6.273      5.032 
         0.000      0.000      0.000      0.000      0.000      8.348      7.848      6.920
share|improve this question
    
It's not a question, it's a dissertation! :) –  Almo Jan 24 '12 at 18:13
    
I have been working on this for days without result, will try to reduce it :) –  Aman Jan 24 '12 at 18:28
    
Looks like a tricky problem. –  Almo Jan 24 '12 at 18:30
    
You do know that with floating points you aren't guaranteed to reproduce results exactly? –  Anycorn Jan 24 '12 at 19:21
2  
The actual calculation part looks fine. The only change in your sequential and parallel versions is the communication. So you should focus on that. And float values don't give the exact same results under certain conditions, but your problem does not qualify for this eccentricity. So you should get the exact same grid values in both the sequential and parallel versions up to at least 6 decimal places for floats and 12 decimal places for double. –  Neo Jan 24 '12 at 21:27

2 Answers 2

Have you thought of trying a debugger on it? I am very biased as I work for an MPI debugger company, but I just downloaded your code, and tried it in Allinea DDT, and it stopped in stencil() when it detected a read beyond the end of your array, initially by process 7.

To reproduce this, compile your code with "-g" for debugging support, and get hold of Allinea DDT from http://www.allinea.com, install it, and turn on Memory Debugging (and ensure you have "Guard Pages" configured Above, with 1 Page in the Memory Debugging settings).

Run your program, with, say, 8 processes, and you should soon find your answer, in seconds.

Good luck!

David

share|improve this answer
    
I downloaded and installed ddt (content.allinea.com/downloads/…), upon trying to run it I got /opt/allinea/ddt/libexec/ddt-splash: 1: Syntax error: ")" unexpected. I am not sure if I executed it correctly, didn't find any forum on allinea.com $ /opt/allinea/ddt/bin/ddt mpirun -n 3 ./sor-par 8 -print –  Aman Jan 31 '12 at 22:23
    
Aman - you probably downloaded the wrong architecture - eg. if your machine is 32-bit you need the 32-bit binaries - I think you've tried a 64 bit binary there. –  David Feb 3 '12 at 15:24

This looks suspect:

MPI_Isend(bufs1, icnt1, MPI_DOUBLE, iprev, 1, MPI_COMM_WORLD, &ireqs1);
MPI_Isend(bufs2, icnt2, MPI_DOUBLE, inext, 1, MPI_COMM_WORLD, &ireqs2);

MPI_Irecv(bufr1, N, MPI_DOUBLE, iprev, 1, MPI_COMM_WORLD, &ireqr1);
MPI_Irecv(bufr2, N, MPI_DOUBLE, inext, 1, MPI_COMM_WORLD, &ireqr2);

MPI_Wait(&ireqs1, &istatus);
MPI_Wait(&ireqs2, &istatus);
MPI_Wait(&ireqr1, &istatus);
MPI_Wait(&ireqr2, &istatus);

I would have expected something like:

MPI_Isend(bufs1, icnt1, MPI_DOUBLE, iprev, 1, MPI_COMM_WORLD, &ireqs1);
MPI_Isend(bufs2, icnt2, MPI_DOUBLE, inext, 1, MPI_COMM_WORLD, &ireqs2);

MPI_Wait(&ireqs1, &istatus);
MPI_Wait(&ireqs2, &istatus);

MPI_Irecv(bufr1, N, MPI_DOUBLE, iprev, 1, MPI_COMM_WORLD, &ireqr1);
MPI_Irecv(bufr2, N, MPI_DOUBLE, inext, 1, MPI_COMM_WORLD, &ireqr2);

MPI_Wait(&ireqs1, &istatus);
MPI_Wait(&ireqs2, &istatus);

And possibly the middle two wait()s are not needed at all.

share|improve this answer
    
i tried your way, it didn't seem to make any difference in final result –  Aman Jan 31 '12 at 22:01

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