607bdf51b6
- new mca param calls - move printfs to OPAL_OUTPUT This commit was SVN r7692.
442 строки
12 KiB
C
442 строки
12 KiB
C
/*
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* Copyright (c) 2004-2005 The Trustees of Indiana University.
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* All rights reserved.
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* Copyright (c) 2004-2005 The Trustees of the University of Tennessee.
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* All rights reserved.
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* Copyright (c) 2004-2005 High Performance Computing Center Stuttgart,
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* University of Stuttgart. All rights reserved.
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* Copyright (c) 2004-2005 The Regents of the University of California.
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* All rights reserved.
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* $COPYRIGHT$
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*
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* Additional copyrights may follow
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*
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* $HEADER$
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*/
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#include "ompi_config.h"
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#include "mpi.h"
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#include "ompi/include/constants.h"
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#include "datatype/datatype.h"
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#include "communicator/communicator.h"
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#include "mca/coll/coll.h"
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#include "mca/coll/base/coll_tags.h"
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#include "mca/pml/pml.h"
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#include "coll_tuned.h"
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#include "coll_tuned_topo.h"
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/*
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* Some static helpers.
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*/
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static int pown( int fanout, int num )
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{
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int j, p = 1;
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if( num < 0 ) return 0;
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for( j = 0; j < num; j++ ) p*= fanout;
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return p;
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}
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static int calculate_level( int fanout, int rank )
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{
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int level, num;
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if( rank < 0 ) return -1;
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for( level = 0, num = 0; num <= rank; level++ ) {
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num += pown(fanout, level);
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}
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return level-1;
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}
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static int calculate_num_nodes_up_to_level( int fanout, int level )
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{
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/* just use geometric progression formula for sum:
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a^0+a^1+...a^(n-1) = (a^n-1)/(a-1) */
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return ((pown(fanout,level) - 1)/(fanout - 1));
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}
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/*
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* And now the building functions.
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*/
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ompi_coll_tree_t*
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ompi_coll_tuned_topo_build_tree( int fanout,
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struct ompi_communicator_t* comm,
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int root )
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{
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int rank, size;
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int schild, sparent;
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int level; /* location of my rank in the tree structure of size */
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int delta; /* number of nodes on my level */
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int slimit; /* total number of nodes on levels above me */
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int shiftedrank;
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int i;
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ompi_coll_tree_t* tree;
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OPAL_OUTPUT((mca_coll_tuned_stream, "coll:tuned:topo_build_tree Building fo %d rt %d", fanout, root));
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if (fanout<1) {
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OPAL_OUTPUT((mca_coll_tuned_stream, "coll:tuned:topo_build_tree invalid fanout %d", fanout));
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return NULL;
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}
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if (fanout>MAXTREEFANOUT) {
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OPAL_OUTPUT((mca_coll_tuned_stream,"coll:tuned:topo_build_tree invalid fanout %d bigger than max %d", fanout, MAXTREEFANOUT));
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return NULL;
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}
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/*
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* Get size and rank of the process in this communicator
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*/
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size = ompi_comm_size(comm);
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rank = ompi_comm_rank(comm);
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tree = (ompi_coll_tree_t*)malloc(sizeof(ompi_coll_tree_t));
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if (!tree) {
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OPAL_OUTPUT((mca_coll_tuned_stream,"coll:tuned:topo_build_tree PANIC::out of memory"));
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return NULL;
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}
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tree->tree_root = MPI_UNDEFINED;
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tree->tree_nextsize = MPI_UNDEFINED;
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/*
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* Set root
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*/
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tree->tree_root = root;
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/*
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* Initialize tree
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*/
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tree->tree_fanout = fanout;
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tree->tree_bmtree = 0;
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tree->tree_root = root;
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tree->tree_prev = -1;
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tree->tree_nextsize = 0;
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for( i = 0; i < fanout; i++ ) {
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tree->tree_next[i] = -1;
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}
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/* return if we have less than 2 processes */
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if( size < 2 ) {
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return tree;
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}
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/*
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* Shift all ranks by root, so that the algorithm can be
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* designed as if root would be always 0
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* shiftedrank should be used in calculating distances
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* and position in tree
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*/
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shiftedrank = rank - root;
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if( shiftedrank < 0 ) {
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shiftedrank += size;
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}
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/* calculate my level */
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level = calculate_level( fanout, shiftedrank );
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delta = pown( fanout, level );
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/* find my children */
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for( i = 0; i < fanout; i++ ) {
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schild = shiftedrank + delta * (i+1);
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if( schild < size ) {
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tree->tree_next[i] = (schild+root)%size;
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tree->tree_nextsize = tree->tree_nextsize + 1;
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} else {
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break;
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}
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}
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/* find my parent */
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slimit = calculate_num_nodes_up_to_level( fanout, level );
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sparent = shiftedrank;
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if( sparent < fanout ) {
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sparent = 0;
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} else {
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while( sparent >= slimit ) {
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sparent -= delta/fanout;
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}
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}
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tree->tree_prev = (sparent+root)%size;
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return tree;
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}
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int ompi_coll_tuned_topo_destroy_tree( ompi_coll_tree_t** tree )
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{
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ompi_coll_tree_t *ptr;
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if ((!tree)||(!*tree)) {
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return OMPI_SUCCESS;
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}
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ptr = *tree;
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free (ptr);
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*tree = NULL; /* mark tree as gone */
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return OMPI_SUCCESS;
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}
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ompi_coll_tree_t*
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ompi_coll_tuned_topo_build_bmtree( struct ompi_communicator_t* comm,
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int root )
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{
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int childs = 0;
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int rank;
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int size;
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int mask = 1;
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int index;
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int remote;
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ompi_coll_tree_t *bmtree;
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int i;
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OPAL_OUTPUT((mca_coll_tuned_stream,"coll:tuned:topo:build_bmtree rt %d", root));
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/*
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* Get size and rank of the process in this communicator
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*/
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size = ompi_comm_size(comm);
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rank = ompi_comm_rank(comm);
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index = rank -root;
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bmtree = (ompi_coll_tree_t*)malloc(sizeof(ompi_coll_tree_t));
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if (!bmtree) {
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OPAL_OUTPUT((mca_coll_tuned_stream,"coll:tuned:topo:build_bmtree PANIC out of memory"));
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return NULL;
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}
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bmtree->tree_bmtree = 1;
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bmtree->tree_root = MPI_UNDEFINED;
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bmtree->tree_nextsize = MPI_UNDEFINED;
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for(i=0;i<MAXTREEFANOUT;i++) {
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bmtree->tree_next[i] = -1;
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}
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if( index < 0 ) index += size;
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while( mask <= index ) mask <<= 1;
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/* Now I can compute my father rank */
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if( root == rank ) {
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bmtree->tree_prev = root;
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} else {
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remote = (index ^ (mask >> 1)) + root;
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if( remote >= size ) remote -= size;
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bmtree->tree_prev = remote;
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}
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/* And now let's fill my childs */
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while( mask < size ) {
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remote = (index ^ mask);
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if( remote >= size ) break;
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remote += root;
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if( remote >= size ) remote -= size;
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if (childs==MAXTREEFANOUT) {
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OPAL_OUTPUT((mca_coll_tuned_stream,"coll:tuned:topo:build_bmtree max fanout incorrect %d needed %d", MAXTREEFANOUT, childs));
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return NULL;
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}
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bmtree->tree_next[childs] = remote;
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mask <<= 1;
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childs++;
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}
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bmtree->tree_nextsize = childs;
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bmtree->tree_root = root;
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return bmtree;
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}
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ompi_coll_chain_t*
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ompi_coll_tuned_topo_build_chain( int fanout,
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struct ompi_communicator_t* comm,
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int root )
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{
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int rank, size;
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int srank; /* shifted rank */
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int i,maxchainlen;
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int mark,head,len;
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ompi_coll_chain_t *chain;
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OPAL_OUTPUT((mca_coll_tuned_stream,"coll:tuned:topo:build_chain fo %d rt %d", fanout, root));
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/*
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* Get size and rank of the process in this communicator
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*/
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size = ompi_comm_size(comm);
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rank = ompi_comm_rank(comm);
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if( fanout < 1 ) {
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return NULL;
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}
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if (fanout>MAXTREEFANOUT) {
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OPAL_OUTPUT((mca_coll_tuned_stream,"coll:tuned:topo:build_chain invalid fanout %d bigger than max %d", fanout, MAXTREEFANOUT));
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return NULL;
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}
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/*
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* Allocate space for topology arrays if needed
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*/
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chain = (ompi_coll_chain_t*)malloc( sizeof(ompi_coll_chain_t) );
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if (!chain) {
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OPAL_OUTPUT((mca_coll_tuned_stream,"coll:tuned:topo:build_chain PANIC out of memory"));
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fflush(stdout);
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return NULL;
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}
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chain->chain_root = MPI_UNDEFINED;
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chain->chain_nextsize = -1;
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chain->chain_numchain = -1;
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for(i=0;i<fanout;i++) chain->chain_next[i] = -1;
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/*
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* Set root & numchain
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*/
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chain->chain_root = root;
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if( (size - 1) < fanout ) {
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chain->chain_numchain = size-1;
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chain->chain_nextsize = size-1;
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fanout = size-1;
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} else {
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chain->chain_numchain = fanout;
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chain->chain_nextsize = fanout;
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}
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/*
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* Shift ranks
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*/
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srank = rank - root;
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if (srank < 0) srank += size;
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/*
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* Special case - fanout == 1
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*/
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if( fanout == 1 ) {
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if( srank == 0 ) chain->chain_prev = -1;
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else chain->chain_prev = (srank-1+root)%size;
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if( (srank + 1) >= size) {
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chain->chain_next[0] = -1;
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chain->chain_nextsize = 0;
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} else {
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chain->chain_next[0] = (srank+1+root)%size;
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chain->chain_nextsize = 1;
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}
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return chain;
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}
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/* Let's handle the case where there is just one node in the communicator */
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if( size == 1 ) {
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chain->chain_next[0] = -1;
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chain->chain_nextsize = 0;
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chain->chain_prev = -1;
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chain->chain_numchain = 0;
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return chain;
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}
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/*
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* Calculate maximum chain length
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*/
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maxchainlen = (size-1) / fanout;
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if( (size-1) % fanout != 0 ) {
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maxchainlen++;
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mark = (size-1)%fanout;
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} else {
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mark = fanout+1;
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}
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/*
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* Find your own place in the list of shifted ranks
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*/
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if( srank != 0 ) {
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int column;
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if( srank-1 < (mark * maxchainlen) ) {
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column = (srank-1)/maxchainlen;
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head = 1+column*maxchainlen;
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len = maxchainlen;
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} else {
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column = mark + (srank-1-mark*maxchainlen)/(maxchainlen-1);
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head = mark*maxchainlen+1+(column-mark)*(maxchainlen-1);
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len = maxchainlen-1;
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}
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if( srank == head ) {
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chain->chain_prev = 0; /*root*/
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} else {
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chain->chain_prev = srank-1; /* rank -1 */
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}
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if( srank == (head + len - 1) ) {
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chain->chain_next[0] = -1;
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chain->chain_nextsize = 0;
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} else {
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if( (srank + 1) < size ) {
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chain->chain_next[0] = srank+1;
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chain->chain_nextsize = 1;
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} else {
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chain->chain_next[0] = -1;
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chain->chain_nextsize = 0;
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}
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}
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}
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/*
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* Unshift values
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*/
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if( rank == root ) {
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chain->chain_prev = -1;
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chain->chain_next[0] = (root+1)%size;
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for( i = 1; i < fanout; i++ ) {
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chain->chain_next[i] = chain->chain_next[i-1] + maxchainlen;
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if( i > mark ) {
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chain->chain_next[i]--;
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}
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chain->chain_next[i] %= size;
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}
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chain->chain_nextsize = fanout;
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} else {
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chain->chain_prev = (chain->chain_prev+root)%size;
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if( chain->chain_next[0] != -1 ) {
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chain->chain_next[0] = (chain->chain_next[0]+root)%size;
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}
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}
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return chain;
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}
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int ompi_coll_tuned_topo_destroy_chain( ompi_coll_chain_t** chain )
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{
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ompi_coll_chain_t *ptr;
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if ((!chain)||(!*chain)) {
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return OMPI_SUCCESS;
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}
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ptr = *chain;
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free (ptr);
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*chain = NULL; /* mark chain as gone */
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return OMPI_SUCCESS;
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}
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int ompi_coll_tuned_topo_dump_tree (ompi_coll_tree_t* tree, int rank)
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{
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int i;
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OPAL_OUTPUT((mca_coll_tuned_stream,"coll:tuned:topo:topo_dump_tree %1d tree root %d fanout %d BM %1d nextsize %d prev %d", rank,
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tree->tree_root, tree->tree_bmtree, tree->tree_fanout, tree->tree_nextsize, tree->tree_prev));
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if (tree->tree_nextsize) {
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for (i=0;i<tree->tree_nextsize;i++) OPAL_OUTPUT((mca_coll_tuned_stream,"[%1d] %d", i, tree->tree_next[i]));
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}
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return (0);
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}
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int ompi_coll_tuned_topo_dump_chain (ompi_coll_chain_t* chain, int rank)
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{
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int i;
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OPAL_OUTPUT((mca_coll_tuned_stream,"coll:tuned:topo:topo_dump_chain %1d chain root %d fanout %d nextsize %d prev %d\n", rank,
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chain->chain_root, chain->chain_numchain, chain->chain_nextsize, chain->chain_prev));
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if (chain->chain_nextsize) {
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for (i=0;i<chain->chain_nextsize;i++) OPAL_OUTPUT((mca_coll_tuned_stream,"[%1d] %d ", i, chain->chain_next[i]));
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}
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return (0);
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}
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