Merge pull request #5644 from mkurnosov/coll-iallreduce-rabenseifner

coll/libnbc: add Rabenseifner's algorithm for MPI_Iallreduce
2018-12-24 12:58:21 -05:00 · 2018-12-24 12:58:21 -05:00 · 593db292da
--- a/ompi/mca/coll/libnbc/coll_libnbc.h
+++ b/ompi/mca/coll/libnbc/coll_libnbc.h
@ -71,6 +71,7 @@ BEGIN_C_DECLS
 extern bool libnbc_ibcast_skip_dt_decision;
 extern int libnbc_iallgather_algorithm;
 extern int libnbc_iallreduce_algorithm;
 extern int libnbc_ibcast_algorithm;
 extern int libnbc_ibcast_knomial_radix;
 extern int libnbc_iexscan_algorithm;
--- a/ompi/mca/coll/libnbc/coll_libnbc_component.c
+++ b/ompi/mca/coll/libnbc/coll_libnbc_component.c
@ -54,6 +54,15 @@ static mca_base_var_enum_value_t iallgather_algorithms[] = {
    {0, NULL}
 };
 int libnbc_iallreduce_algorithm = 0;             /* iallreduce user forced algorithm */
 static mca_base_var_enum_value_t iallreduce_algorithms[] = {
    {0, "ignore"},
    {1, "ring"},
    {2, "binomial"},
    {3, "rabenseifner"},
    {0, NULL}
 };
 int libnbc_ibcast_algorithm = 0;             /* ibcast user forced algorithm */
 int libnbc_ibcast_knomial_radix = 4;
 static mca_base_var_enum_value_t ibcast_algorithms[] = {
@ -97,7 +106,6 @@ static int libnbc_init_query(bool, bool);
 static mca_coll_base_module_t *libnbc_comm_query(struct ompi_communicator_t *, int *);
 static int libnbc_module_enable(mca_coll_base_module_t *, struct ompi_communicator_t *);
 /*
 * Instantiate the public struct with all of our public information
 * and pointers to our public functions in it
@ -213,6 +221,16 @@ libnbc_register(void)
                                    &libnbc_iallgather_algorithm);
    OBJ_RELEASE(new_enum);
    libnbc_iallreduce_algorithm = 0;
    (void) mca_base_var_enum_create("coll_libnbc_iallreduce_algorithms", iallreduce_algorithms, &new_enum);
    mca_base_component_var_register(&mca_coll_libnbc_component.super.collm_version,
                                    "iallreduce_algorithm",
                                    "Which iallreduce algorithm is used: 0 ignore, 1 ring, 2 binomial, 3 rabenseifner",
                                    MCA_BASE_VAR_TYPE_INT, new_enum, 0, MCA_BASE_VAR_FLAG_SETTABLE,
                                    OPAL_INFO_LVL_5, MCA_BASE_VAR_SCOPE_ALL,
                                    &libnbc_iallreduce_algorithm);
    OBJ_RELEASE(new_enum);
    libnbc_ibcast_algorithm = 0;
    (void) mca_base_var_enum_create("coll_libnbc_ibcast_algorithms", ibcast_algorithms, &new_enum);
    mca_base_component_var_register(&mca_coll_libnbc_component.super.collm_version,
@ -264,8 +282,6 @@ libnbc_register(void)
    return OMPI_SUCCESS;
 }
 /*
 * Initial query function that is invoked during MPI_INIT, allowing
 * this component to disqualify itself if it doesn't support the
--- a/ompi/mca/coll/libnbc/nbc_iallreduce.c
+++ b/ompi/mca/coll/libnbc/nbc_iallreduce.c
@ -22,6 +22,7 @@
 #include "ompi/communicator/communicator.h"
 #include "ompi/datatype/ompi_datatype.h"
 #include "ompi/op/op.h"
 #include "opal/util/bit_ops.h"
 #include <assert.h>
@ -33,6 +34,10 @@ static inline int allred_sched_ring(int rank, int p, int count, MPI_Datatype dat
 static inline int allred_sched_linear(int rank, int p, const void *sendbuf, void *recvbuf, int count,
                                      MPI_Datatype datatype, ptrdiff_t gap, MPI_Op op, int ext, int size,
                                      NBC_Schedule *schedule, void *tmpbuf);
 static inline int allred_sched_redscat_allgather(
    int rank, int comm_size, int count, MPI_Datatype datatype, ptrdiff_t gap,
    const void *sbuf, void *rbuf, MPI_Op op, char inplace,
    NBC_Schedule *schedule, void *tmpbuf, struct ompi_communicator_t *comm);
 #ifdef NBC_CACHE_SCHEDULE
 /* tree comparison function for schedule cache */
@ -64,7 +69,7 @@ static int nbc_allreduce_init(const void* sendbuf, void* recvbuf, int count, MPI
 #ifdef NBC_CACHE_SCHEDULE
  NBC_Allreduce_args *args, *found, search;
 #endif
-  enum { NBC_ARED_BINOMIAL, NBC_ARED_RING } alg;
+  enum { NBC_ARED_BINOMIAL, NBC_ARED_RING, NBC_ARED_REDSCAT_ALLGATHER } alg;
  char inplace;
  void *tmpbuf = NULL;
  ompi_coll_libnbc_module_t *libnbc_module = (ompi_coll_libnbc_module_t*) module;
@ -105,12 +110,25 @@ static int nbc_allreduce_init(const void* sendbuf, void* recvbuf, int count, MPI
  }
  /* algorithm selection */
  int nprocs_pof2 = opal_next_poweroftwo(p) >> 1;
  if (libnbc_iallreduce_algorithm == 0) {
    if(p < 4 || size*count < 65536 || !ompi_op_is_commute(op) || inplace) {
      alg = NBC_ARED_BINOMIAL;
    } else if (count >= nprocs_pof2 && ompi_op_is_commute(op)) {
      alg = NBC_ARED_REDSCAT_ALLGATHER;
    } else {
      alg = NBC_ARED_RING;
    }
-
+  } else {
    if (libnbc_iallreduce_algorithm == 1)
      alg = NBC_ARED_RING;
    else if (libnbc_iallreduce_algorithm == 2)
      alg = NBC_ARED_BINOMIAL;
    else if (libnbc_iallreduce_algorithm == 3 && count >= nprocs_pof2 && ompi_op_is_commute(op)) {
      alg = NBC_ARED_REDSCAT_ALLGATHER;
    } else
      alg = NBC_ARED_RING;
  }
 #ifdef NBC_CACHE_SCHEDULE
  /* search schedule in communicator specific tree */
  search.sendbuf = sendbuf;
@ -135,6 +153,9 @@ static int nbc_allreduce_init(const void* sendbuf, void* recvbuf, int count, MPI
        case NBC_ARED_BINOMIAL:
          res = allred_sched_diss(rank, p, count, datatype, gap, sendbuf, recvbuf, op, inplace, schedule, tmpbuf);
          break;
        case NBC_ARED_REDSCAT_ALLGATHER:
          res = allred_sched_redscat_allgather(rank, p, count, datatype, gap, sendbuf, recvbuf, op, inplace, schedule, tmpbuf, comm);
          break;
        case NBC_ARED_RING:
          res = allred_sched_ring(rank, p, count, datatype, sendbuf, recvbuf, op, size, ext, schedule, tmpbuf);
          break;
@ -735,6 +756,271 @@ static inline int allred_sched_linear(int rank, int rsize, const void *sendbuf,
  return OMPI_SUCCESS;
 }
 /*
 * allred_sched_redscat_allgather:
 *
 * Description: an implementation of Rabenseifner's Allreduce algorithm [1, 2].
 *   [1] Rajeev Thakur, Rolf Rabenseifner and William Gropp.
 *       Optimization of Collective Communication Operations in MPICH //
 *       The Int. Journal of High Performance Computing Applications. Vol 19,
 *       Issue 1, pp. 49--66.
 *   [2] http://www.hlrs.de/mpi/myreduce.html.
 *
 * This algorithm is a combination of a reduce-scatter implemented with
 * recursive vector halving and recursive distance doubling, followed either
 * by an allgather implemented with recursive doubling.
 *
 * Step 1. If the number of processes is not a power of two, reduce it to
 * the nearest lower power of two (p' = 2^{\floor{\log_2 p}})
 * by removing r = p - p' extra processes as follows. In the first 2r processes
 * (ranks 0 to 2r - 1), all the even ranks send the second half of the input
 * vector to their right neighbor (rank + 1), and all the odd ranks send
 * the first half of the input vector to their left neighbor (rank - 1).
 * The even ranks compute the reduction on the first half of the vector and
 * the odd ranks compute the reduction on the second half. The odd ranks then
 * send the result to their left neighbors (the even ranks). As a result,
 * the even ranks among the first 2r processes now contain the reduction with
 * the input vector on their right neighbors (the odd ranks). These odd ranks
 * do not participate in the rest of the algorithm, which leaves behind
 * a power-of-two number of processes. The first r even-ranked processes and
 * the last p - 2r processes are now renumbered from 0 to p' - 1.
 *
 * Step 2. The remaining processes now perform a reduce-scatter by using
 * recursive vector halving and recursive distance doubling. The even-ranked
 * processes send the second half of their buffer to rank + 1 and the odd-ranked
 * processes send the first half of their buffer to rank - 1. All processes
 * then compute the reduction between the local buffer and the received buffer.
 * In the next log_2(p') - 1 steps, the buffers are recursively halved, and the
 * distance is doubled. At the end, each of the p' processes has 1 / p' of the
 * total reduction result.
 *
 * Step 3. An allgather is performed by using recursive vector doubling and
 * distance halving. All exchanges are executed in reverse order relative
 * to recursive doubling on previous step. If the number of processes is not
 * a power of two, the total result vector must be sent to the r processes
 * that were removed in the first step.
 *
 * Limitations:
 *   count >= 2^{\floor{\log_2 p}}
 *   commutative operations only
 *   intra-communicators only
 *
 * Memory requirements (per process):
 *   count * typesize + 4 * \log_2(p) * sizeof(int) = O(count)
 *
 * Schedule length (rounds): O(\log(p))
 */
 static inline int allred_sched_redscat_allgather(
    int rank, int comm_size, int count, MPI_Datatype datatype, ptrdiff_t gap,
    const void *sbuf, void *rbuf, MPI_Op op, char inplace,
    NBC_Schedule *schedule, void *tmpbuf, struct ompi_communicator_t *comm)
 {
    int res = OMPI_SUCCESS;
    int *rindex = NULL, *rcount = NULL, *sindex = NULL, *scount = NULL;
     /* Find nearest power-of-two less than or equal to comm_size */
    int nsteps = opal_hibit(comm_size, comm->c_cube_dim + 1);   /* ilog2(comm_size) */
    int nprocs_pof2 = 1 << nsteps;                              /* flp2(comm_size) */
     if (!inplace) {
        res = NBC_Sched_copy((char *)sbuf, false, count, datatype,
                             rbuf, false, count, datatype, schedule, true);
        if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
    }
    char *tmp_buf = (char *)tmpbuf - gap;
    ptrdiff_t lb, extent;
    ompi_datatype_get_extent(datatype, &lb, &extent);
     /*
     * Step 1. Reduce the number of processes to the nearest lower power of two
     * p' = 2^{\floor{\log_2 p}} by removing r = p - p' processes.
     * 1. In the first 2r processes (ranks 0 to 2r - 1), all the even ranks send
     *    the second half of the input vector to their right neighbor (rank + 1)
     *    and all the odd ranks send the first half of the input vector to their
     *    left neighbor (rank - 1).
     * 2. All 2r processes compute the reduction on their half.
     * 3. The odd ranks then send the result to their left neighbors
     *    (the even ranks).
     *
     * The even ranks (0 to 2r - 1) now contain the reduction with the input
     * vector on their right neighbors (the odd ranks). The first r even
     * processes and the p - 2r last processes are renumbered from
     * 0 to 2^{\floor{\log_2 p}} - 1.
     */
    int vrank, step, wsize;
    int nprocs_rem = comm_size - nprocs_pof2;
     if (rank < 2 * nprocs_rem) {
        int count_lhalf = count / 2;
        int count_rhalf = count - count_lhalf;
         if (rank % 2 != 0) {
            /*
             * Odd process -- exchange with rank - 1
             * Send the left half of the input vector to the left neighbor,
             * Recv the right half of the input vector from the left neighbor
             */
            res = NBC_Sched_send(rbuf, false, count_lhalf, datatype, rank - 1,
                                 schedule, false);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
             res = NBC_Sched_recv(tmp_buf + (ptrdiff_t)count_lhalf * extent,
                                 false, count_rhalf, datatype, rank - 1, schedule, true);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
             res = NBC_Sched_op(tmp_buf + (ptrdiff_t)count_lhalf * extent,
                               false, (char *)rbuf + (ptrdiff_t)count_lhalf * extent,
                               false, count_rhalf, datatype, op, schedule, true);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
             /* Send the right half to the left neighbor */
            res = NBC_Sched_send((char *)rbuf + (ptrdiff_t)count_lhalf * extent,
                                 false, count_rhalf, datatype, rank - 1, schedule, true);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
             /* This process does not participate in recursive doubling phase */
            vrank = -1;
         } else {
            /*
             * Even process -- exchange with rank + 1
             * Send the right half of the input vector to the right neighbor,
             * Recv the left half of the input vector from the right neighbor
             */
            res = NBC_Sched_send((char *)rbuf + (ptrdiff_t)count_lhalf * extent,
                                 false, count_rhalf, datatype, rank + 1, schedule, false);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
             res = NBC_Sched_recv(tmp_buf, false, count_lhalf, datatype, rank + 1,
                                 schedule, true);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
             res = NBC_Sched_op(tmp_buf, false, rbuf, false, count_lhalf,
                               datatype, op, schedule, true);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
             /* Recv the right half from the right neighbor */
            res = NBC_Sched_recv((char *)rbuf + (ptrdiff_t)count_lhalf * extent,
                                 false, count_rhalf, datatype, rank + 1, schedule, true);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
             vrank = rank / 2;
        }
    } else { /* rank >= 2 * nprocs_rem */
        vrank = rank - nprocs_rem;
    }
     /*
     * Step 2. Reduce-scatter implemented with recursive vector halving and
     * recursive distance doubling. We have p' = 2^{\floor{\log_2 p}}
     * power-of-two number of processes with new ranks (vrank) and result in rbuf.
     *
     * The even-ranked processes send the right half of their buffer to rank + 1
     * and the odd-ranked processes send the left half of their buffer to
     * rank - 1. All processes then compute the reduction between the local
     * buffer and the received buffer. In the next \log_2(p') - 1 steps, the
     * buffers are recursively halved, and the distance is doubled. At the end,
     * each of the p' processes has 1 / p' of the total reduction result.
     */
    rindex = malloc(sizeof(*rindex) * nsteps);
    sindex = malloc(sizeof(*sindex) * nsteps);
    rcount = malloc(sizeof(*rcount) * nsteps);
    scount = malloc(sizeof(*scount) * nsteps);
    if (NULL == rindex || NULL == sindex || NULL == rcount || NULL == scount) {
        res = OMPI_ERR_OUT_OF_RESOURCE;
        goto cleanup_and_return;
    }
     if (vrank != -1) {
        step = 0;
        wsize = count;
        sindex[0] = rindex[0] = 0;
         for (int mask = 1; mask < nprocs_pof2; mask <<= 1) {
            /*
             * On each iteration: rindex[step] = sindex[step] -- begining of the
             * current window. Length of the current window is storded in wsize.
             */
            int vdest = vrank ^ mask;
            /* Translate vdest virtual rank to real rank */
            int dest = (vdest < nprocs_rem) ? vdest * 2 : vdest + nprocs_rem;
             if (rank < dest) {
                /*
                 * Recv into the left half of the current window, send the right
                 * half of the window to the peer (perform reduce on the left
                 * half of the current window)
                 */
                rcount[step] = wsize / 2;
                scount[step] = wsize - rcount[step];
                sindex[step] = rindex[step] + rcount[step];
            } else {
                /*
                 * Recv into the right half of the current window, send the left
                 * half of the window to the peer (perform reduce on the right
                 * half of the current window)
                 */
                scount[step] = wsize / 2;
                rcount[step] = wsize - scount[step];
                rindex[step] = sindex[step] + scount[step];
            }
             /* Send part of data from the rbuf, recv into the tmp_buf */
            res = NBC_Sched_send((char *)rbuf + (ptrdiff_t)sindex[step] * extent,
                                 false, scount[step], datatype, dest, schedule, false);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
            res = NBC_Sched_recv((char *)tmp_buf + (ptrdiff_t)rindex[step] * extent,
                                 false, rcount[step], datatype, dest, schedule, true);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
             /* Local reduce: rbuf[] = tmp_buf[] <op> rbuf[] */
            res = NBC_Sched_op((char *)tmp_buf + (ptrdiff_t)rindex[step] * extent,
                               false, (char *)rbuf + (ptrdiff_t)rindex[step] * extent,
                               false, rcount[step], datatype, op, schedule, true);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
             /* Move the current window to the received message */
            if (step + 1 < nsteps) {
                rindex[step + 1] = rindex[step];
                sindex[step + 1] = rindex[step];
                wsize = rcount[step];
                step++;
            }
        }
        /*
         * Assertion: each process has 1 / p' of the total reduction result:
         * rcount[nsteps - 1] elements in the rbuf[rindex[nsteps - 1], ...].
         */
         /*
         * Step 3. Allgather by the recursive doubling algorithm.
         * Each process has 1 / p' of the total reduction result:
         * rcount[nsteps - 1] elements in the rbuf[rindex[nsteps - 1], ...].
         * All exchanges are executed in reverse order relative
         * to recursive doubling (previous step).
         */
        step = nsteps - 1;
         for (int mask = nprocs_pof2 >> 1; mask > 0; mask >>= 1) {
            int vdest = vrank ^ mask;
            /* Translate vdest virtual rank to real rank */
            int dest = (vdest < nprocs_rem) ? vdest * 2 : vdest + nprocs_rem;
             /*
             * Send rcount[step] elements from rbuf[rindex[step]...]
             * Recv scount[step] elements to rbuf[sindex[step]...]
             */
            res = NBC_Sched_send((char *)rbuf + (ptrdiff_t)rindex[step] * extent,
                                 false, rcount[step], datatype, dest, schedule, false);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
            res = NBC_Sched_recv((char *)rbuf + (ptrdiff_t)sindex[step] * extent,
                                 false, scount[step], datatype, dest, schedule, true);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
            step--;
        }
    }
     /*
     * Step 4. Send total result to excluded odd ranks.
     */
    if (rank < 2 * nprocs_rem) {
        if (rank % 2 != 0) {
            /* Odd process -- recv result from rank - 1 */
            res = NBC_Sched_recv(rbuf, false, count, datatype, rank - 1, schedule, false);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
        } else {
            /* Even process -- send result to rank + 1 */
            res = NBC_Sched_send(rbuf, false, count, datatype, rank + 1, schedule, false);
            if (OPAL_UNLIKELY(OMPI_SUCCESS != res)) { goto cleanup_and_return; }
        }
    }
   cleanup_and_return:
    if (NULL != rindex)
        free(rindex);
    if (NULL != sindex)
        free(sindex);
    if (NULL != rcount)
        free(rcount);
    if (NULL != scount)
        free(scount);
    return res;
 }
 int ompi_coll_libnbc_allreduce_init(const void* sendbuf, void* recvbuf, int count, MPI_Datatype datatype, MPI_Op op,
                                    struct ompi_communicator_t *comm, MPI_Info info, ompi_request_t ** request,
                                    struct mca_coll_base_module_2_3_0_t *module) {