SHMEM_BROADCAST(3)SHMEM_BROADCAST(3) NAME shmem_broadcast4, shmem_broadcast8, shmem_broadcast32, shmem_broadcast64 - Broadcasts a block of data from one processing element (PE) to one or more target PEs SYNOPSIS C or C++: #include <mpp/shmem.h> void shmem_broadcast32(void *target, const void *source, size_t nlong, int PE_root, int PE_start, int logPE_stride, int PE_size, long *pSync); void shmem_broadcast64(void *target, const void *source, size_t nlong, int PE_root, int PE_start, int logPE_stride, int PE_size, long *pSync); Fortran: INCLUDE "mpp/shmem.fh" INTEGER nlong, PE_root, PE_start, logPE_stride, PE_size INTEGER pSync(SHMEM_BCAST_SYNC_SIZE) CALL SHMEM_BROADCAST4(target, source, nlong, PE_root, PE_start, logPE_stride, PE_size, fIpSync) CALL SHMEM_BROADCAST8(target, source, nlong, PE_root, PE_start, logPE_stride, PE_size, pSync) CALL SHMEM_BROADCAST32(target, source, nlong, PE_root, PE_start, logPE_stride, PE_size, pSync) CALL SHMEM_BROADCAST64(target, source, nlong, PE_root, PE_start, logPE_stride, PE_size, pSync) DESCRIPTION The shared memory (SHMEM) broadcast routines are collective routines. They copy data object source on the processor specified by PE_root and store the values at target on the other PEs specified by the triplet PE_start, logPE_stride, PE_size. The data is not copied to the target area on the root PE. As with all SHMEM collective routines, each of these routines assumes that only PEs in the active set call the routine. If a PE not in the active set calls a SHMEM collective routine, undefined behavior results. The arguments are as follows: target A symmetric data object with one of the following data types: Routine Data Type and Language shmem_broadcast8, shmem_broadcast64 Any noncharacter type that has an element size of 64 bits. No Fortran derived types or C/C++ structures are allowed. shmem_broadcast32 Any noncharacter type that has an element size of 32 bits. No Fortran derived types or C/C++ structures are allowed. shmem_broadcast4 Any noncharacter type that has an element size of 32 bits. source A symmetric data object that can be of any data type that is permissible for the target argument. nlong The number of elements in source. For shmem_broadcast32 and shmem_broadcast4, this is the number of 32-bit halfwords. nlong must be of type integer. If you are using Fortran, it must be a default integer value. PE_root Zero-based ordinal of the PE, with respect to the active set, from which the data is copied. Must be greater than or equal to 0 and less than PE_size. PE_root must be of type integer. If you are using Fortran, it must be a default integer value. PE_start The lowest virtual PE number of the active set of PEs. PE_start must be of type integer. If you are using Fortran, it must be a default integer value. logPE_stride The log (base 2) of the stride between consecutive virtual PE numbers in the active set. log_PE_stride must be of type integer. If you are using Fortran, it must be a default integer value. PE_size The number of PEs in the active set. PE_size must be of type integer. If you are using Fortran, it must be a default integer value. pSync A symmetric work array. In C/C++, pSync must be of type long and size _SHMEM_BCAST_SYNC_SIZE. In Fortran, pSync must be of type integer and size SHMEM_BCAST_SYNC_SIZE. Every element of this array must be initialized with the value _SHMEM_SYNC_VALUE (in C/C++) or SHMEM_SYNC_VALUE (in Fortran) before any of the PEs in the active set enter shmem_barrier(). The values of arguments PE_root, PE_start, logPE_stride, and PE_size must be equal on all PEs in the active set. The same target and source data objects and the same pSync work array must be passed to all PEs in the active set. Before any PE calls a broadcast routine, you must ensure that the following conditions exist (synchronization via a barrier or some other method is often needed to ensure this): * The pSync array on all PEs in the active set is not still in use from a prior call to a broadcast routine. * The target array on all PEs in the active set is ready to accept the broadcast data. Upon return from a broadcast routine, the following are true for the local PE: * If the current PE is not the root PE, the target data object is updated. * The values in the pSync array are restored to the original values. NOTES The terms collective and symmetric are defined in intro_shmem(3). All SHMEM broadcast routines restore pSync to its original contents. Multiple calls to SHMEM routines that use the same pSync array do not require that pSync be reinitialized after the first call. You must ensure the that the pSync array is not being updated by any PE in the active set while any of the PEs participates in processing of a SHMEM broadcast routine. Be careful to avoid these situations: * If the pSync array is initialized at run time, some type of synchronization is needed to ensure that all PEs in the working set have initialized pSync before any of them enter a SHMEM routine called with the pSync synchronization array. * A pSync array may be reused on a subsequent SHMEM broadcast routine only if none of the PEs in the active set are still processing a prior SHMEM broadcast routine call that used the same pSync array. In general, this can be ensured only by doing some type of synchronization. However, in the special case of SHMEM routines being called with the same active set, you can allocate two pSync arrays and alternate between them on successive calls. EXAMPLES In the following examples, the call to shmem_broadcast64 copies source on PE 4 to target on PEs 5, 6, and 7. C/C++ example: for (i=0; i < _SHMEM_BCAST_SYNC_SIZE; i++) { pSync[i] = _SHMEM_SYNC_VALUE; } shmem_barrier_all(); /* Wait for all PEs to initialize pSync */ shmem_broadcast64(target, source, nlong, 0, 4, 0, 4, pSync); Fortran example: INTEGER PSYNC(SHMEM_BCAST_SYNC_SIZE) INTEGER TARGET, SOURCE, NLONG, PE_ROOT, PE_START, & LOGPE_STRIDE, PE_SIZE, PSYNC COMMON /COM/ TARGET, SOURCE DATA PSYNC /SHMEM_BCAST_SYNC_SIZE*SHMEM_SYNC_VALUE/ CALL SHMEM_BROADCAST64(TARGET, SOURCE, NLONG, 0, 4, 0, 4, PSYNC) SEE ALSO intro_shmem(3) Message Passing Toolkit: MPI Programmer's Manual