Correctness


Up: Collective Communication Next: Groups, Contexts, and Communicators Previous: Example using MPI_SCAN

A correct, portable program must invoke collective communications so that deadlock will not occur, whether collective communications are synchronizing or not. The following examples illustrate dangerous use of collective routines. 


  
 

 
The following is erroneous. 

 
 

switch(rank) { 
    case 0: 
        MPI_Bcast(buf1, count, type, 0, comm); 
        MPI_Bcast(buf2, count, type, 1, comm); 
        break; 
    case 1: 
        MPI_Bcast(buf2, count, type, 1, comm); 
        MPI_Bcast(buf1, count, type, 0, comm); 
        break; 
} 

 
We assume that the group of  comm is {0,1}.
 
Two processes execute two broadcast operations in reverse order.  If
 
the operation is synchronizing then a deadlock will occur.
 

 
Collective
 
operations must be executed in the same order at all members of the
 
communication group.
 

 


  
 

 
The following is erroneous. 

 
 

switch(rank) { 
    case 0: 
        MPI_Bcast(buf1, count, type, 0, comm0); 
        MPI_Bcast(buf2, count, type, 2, comm2); 
        break; 
    case 1: 
        MPI_Bcast(buf1, count, type, 1, comm1); 
        MPI_Bcast(buf2, count, type, 0, comm0); 
        break; 
    case 2: 
        MPI_Bcast(buf1, count, type, 2, comm2); 
        MPI_Bcast(buf2, count, type, 1, comm1); 
        break; 
} 

 
Assume that the group of
 
 comm0 is {0,1}, of  comm1 is {1, 2} and of  comm2
 
is {2,0}.  If the broadcast is a synchronizing operation, then there
 
is a cyclic dependency: the broadcast in  comm2 completes only
 
after the broadcast in  comm0; the broadcast in  comm0
 
completes only after the broadcast in  comm1; and the broadcast
 
in  comm1 completes only after the broadcast in  comm2.
 
Thus, the code will deadlock.
 

 
Collective operations must be executed in an order so that
 
no cyclic dependences occur.
 

 


  
 

 
The following is erroneous. 

 
 

switch(rank) { 
    case 0: 
        MPI_Bcast(buf1, count, type, 0, comm); 
        MPI_Send(buf2, count, type, 1, tag, comm); 
        break; 
    case 1: 
        MPI_Recv(buf2, count, type, 0, tag, comm, status); 
        MPI_Bcast(buf1, count, type, 0, comm); 
        break; 
} 

 
Process zero executes a broadcast, followed by a blocking send operation.
 
Process one first executes a blocking receive that matches the send,
 
followed by broadcast call that matches the broadcast of process zero.
 
This program may deadlock.  The broadcast call on process zero
 
 may block until process one executes the matching
 
broadcast call, so that the
 
send is not executed.  Process one will definitely block on the
 
receive and so, in this case, never executes the
 
broadcast.
 

 
The relative order of execution of collective operations and point-to-point
 
operations should be such, so that even if the collective
 
operations and the point-to-point operations are synchronizing, no
 
deadlock will occur.
 
 

  
 

 
A correct, but non-deterministic program. 

 
 

switch(rank) { 
    case 0: 
        MPI_Bcast(buf1, count, type, 0, comm); 
        MPI_Send(buf2, count, type, 1, tag, comm); 
        break; 
    case 1: 
        MPI_Recv(buf2, count, type, MPI_ANY_SOURCE, tag, comm, status); 
        MPI_Bcast(buf1, count, type, 0, comm); 
        MPI_Recv(buf2, count, type, MPI_ANY_SOURCE, tag, comm, status); 
        break; 
    case 2: 
        MPI_Send(buf2, count, type, 1, tag, comm); 
        MPI_Bcast(buf1, count, type, 0, comm); 
        break; 
} 

 
All three processes participate in a broadcast.  Process 0 sends a message to
 
process 1 after the broadcast, and process 2 sends a message
 
to process 1 before
 
the broadcast.  Process 1 receives before and after the broadcast, with a
 
wildcard source argument.
 

 
Two possible executions of this program, with different matchings
 
of sends and receives, are
 
illustrated in figure 11
.
 
Note that the second execution has the peculiar effect that a send executed
 
after the broadcast is received at another node before the broadcast.
 
This example illustrates the fact that one should not rely on
 
collective communication functions to have particular synchronization
 
effects.
 
A program that works correctly only when the first execution occurs
 
(only when broadcast is synchronizing) is erroneous.
figure=coll-matchings.ps,width=4.00in
Figure 11: A race condition causes non-deterministic matching of sends and receives. One cannot rely on synchronization from a broadcast to make the program deterministic.

Finally, in multithreaded implementations, one can have more than one, concurrently executing, collective communication call at a process. In these situations, it is the user's responsibility to ensure that the same communicator is not used concurrently by two different collective communication calls at the same process.


[] Advice to implementors.

Assume that broadcast is implemented using point-to-point MPI communication. Suppose the following two rules are followed.

    1. All receives specify their source explicitly (no wildcards).
    2. Each process sends all messages that pertain to one collective call before sending any message that pertain to a subsequent collective call.
Then, messages belonging to successive broadcasts cannot be confused, as the order of point-to-point messages is preserved.

It is the implementor's responsibility to ensure that point-to-point messages are not confused with collective messages. One way to accomplish this is, whenever a communicator is created, to also create a ``hidden communicator'' for collective communication. One could achieve a similar effect more cheaply, for example, by using a hidden tag or context bit to indicate whether the communicator is used for point-to-point or collective communication. ( End of advice to implementors.)


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