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openmpi/ompi/mca/coll/ml/coll_ml_select.c

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C
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Adding Hierarchical Collectives project to the Open MPI trunk. The project includes following components and frameworks: - ML Collective component - NETPATTERNS and COMMPATTERNS common components - BCOL framework - SBGP framework Note: By default the ML collective component is disabled. In order to enable new collectives user should bump up the priority of ml component (coll_ml_priority) ============================================= Primary Contributors (in alphabetical order): Ishai Rabinovich (Mellanox) Joshua S. Ladd (ORNL / Mellanox) Manjunath Gorentla Venkata (ORNL) Mike Dubman (Mellanox) Noam Bloch (Mellanox) Pavel (Pasha) Shamis (ORNL / Mellanox) Richard Graham (ORNL / Mellanox) Vasily Filipov (Mellanox) This commit was SVN r27078.
2012-08-16 23:11:35 +04:00
/*
* Code for selecting a collective function. The selection is based on
* comm-time attributes and invoke-time attributes.
*
* comm-time attributes: Attributes, which can used to filter available
* collective functions at communicator init time. Example attributes include
* comm size and msg size supported by bcols.
*
* invoke-time attributes: Attributes, which can be used to select function
* for given collective when a collective is invoked.
*
*/
#include "coll_ml_select.h"
static int msg_to_range(size_t msg_len)
{
int range;
if (msg_len < MSG_RANGE_INITIAL) {
return 1;
}
range = (int) log10((double)((msg_len / MSG_RANGE_INITIAL)));
if (range > NUM_MSG_RANGES)
return NUM_MSG_RANGES;
return range;
}
static int cmp_comm_attribs(struct mca_bcol_base_coll_fn_comm_attributes_t *attrib_var,
struct mca_bcol_base_coll_fn_comm_attributes_t *attrib_bcol){
if (!(attrib_var->comm_size_max <= attrib_bcol->comm_size_max)) {
return -1 ;
}
#if 0 /* Manju: pelase fix it*/
if (attrib_var->data_src != attrib_bcol->data_src) {
return -1;
}
if (attrib_var->waiting_semantics !=
attrib_bcol->waiting_semantics) {
return -1;
}
#endif
return 0;
}
/*
* Table that holds function names
*/
static int init_invoke_table(mca_coll_ml_module_t *ml_module)
{
int i=0,j=0,k=0, index_topo;
int bcoll_type;
struct mca_bcol_base_module_t *bcol_module = NULL;
int j_bcol_module=0;
int i_hier=0;
mca_coll_ml_topology_t *topo;
for (index_topo = 0; index_topo < COLL_ML_TOPO_MAX; index_topo++) {
topo = &ml_module->topo_list[index_topo];
if (COLL_ML_TOPO_DISABLED == topo->status) {
/* skip the topology */
continue;
}
for (i_hier = 0; i_hier < topo->n_levels; i_hier++) {
for (j_bcol_module = 0;
j_bcol_module < topo->component_pairs[i_hier].num_bcol_modules;
++j_bcol_module) {
bcol_module = topo->component_pairs[i_hier].bcol_modules[j_bcol_module];
for (bcoll_type = 0; bcoll_type < BCOL_NUM_OF_FUNCTIONS ; bcoll_type++){
for (i=0; i<NUM_MSG_RANGES; i++) {
for (j=0; j<OMPI_OP_NUM_OF_TYPES; j++) {
for (k=0; k<OMPI_DATATYPE_MAX_PREDEFINED; k++) {
bcol_module->filtered_fns_table[DATA_SRC_UNKNOWN][BLOCKING][bcoll_type][i][j][k]
= NULL;
bcol_module->filtered_fns_table[DATA_SRC_KNOWN][BLOCKING][bcoll_type][i][j][k]
= NULL;
bcol_module->filtered_fns_table[DATA_SRC_UNKNOWN][NON_BLOCKING][bcoll_type][i][j][k]
= NULL;
bcol_module->filtered_fns_table[DATA_SRC_KNOWN][NON_BLOCKING][bcoll_type][i][j][k]
= NULL;
}
}
}
}
}
}
}
return 0;
}
static int add_to_invoke_table(mca_bcol_base_module_t *bcol_module,
mca_bcol_base_coll_fn_desc_t *fn_filtered,
mca_coll_ml_module_t *ml_module)
{
struct mca_bcol_base_coll_fn_invoke_attributes_t *inv_attribs = NULL;
int bcoll_type, data_src_type, waiting_semantic;
int range_min,range_max;
int i=0,j=0,k=0,mask=1;
if((NULL == fn_filtered->inv_attr)||(NULL == fn_filtered->comm_attr)) {
return OMPI_ERROR;
}
ML_VERBOSE(10, ("Calling add_to_invoke_table %p",fn_filtered->coll_fn));
inv_attribs = fn_filtered->inv_attr;
bcoll_type = fn_filtered->comm_attr->bcoll_type;
data_src_type = fn_filtered->comm_attr->data_src;
waiting_semantic = fn_filtered->comm_attr->waiting_semantics;
range_min = msg_to_range(inv_attribs->bcol_msg_min);
range_max = msg_to_range(inv_attribs->bcol_msg_max);
for (j=0; j<OMPI_OP_NUM_OF_TYPES; j++) {
for (k=0; k<OMPI_DATATYPE_MAX_PREDEFINED; k++) {
if ((inv_attribs->datatype_bitmap & (mask << k)) && (inv_attribs->op_types_bitmap & (mask << j))){
for (i=range_min; i<=range_max; i++) {
bcol_module->filtered_fns_table[data_src_type][waiting_semantic][bcoll_type][i][j][k]
= fn_filtered;
ML_VERBOSE(11, ("Putting functions %d %d %d %d %p", bcoll_type, i, j, k, fn_filtered));
}
}
}
}
return 0;
}
/*
* Maps count to msg range that is used for
* function table
* RANGE 0 is for small messages (say small msg =10k)
* MSG RANGE 1 - 10K - 100K
* RANGE 2 - 100K -1M
* RANGE 3 - 1M - 10M
*
* This is valid only when MSG_RANGE_INC is 10.
* For other values the function should replace log10 to log with
* base=MSG_RANGE_INC
*/
static int count_to_msg_range(int count,struct ompi_datatype_t *dtype)
{
size_t msg_len =0,dt_size;
int range = 0 ;
ompi_datatype_type_size(dtype, &dt_size);
msg_len = count*dt_size;
if (msg_len < MSG_RANGE_INITIAL) {
return 1;
}
range = (int) log10((double)((msg_len/MSG_RANGE_INITIAL)));
if (range > NUM_MSG_RANGES)
return NUM_MSG_RANGES;
return range;
}
/* Based on the attributes filled in comm_select_attributes
select functions for invoke time filtering */
static int build_algorithms_table(mca_coll_ml_module_t *ml_module,struct
mca_bcol_base_coll_fn_comm_attributes_t *my_comm_attrib)
{
int i_hier, j_bcol_module, k_bcol_fn, index_topo;
struct mca_bcol_base_module_t *bcol_module = NULL;
opal_list_t *fn_filtered_list;
opal_list_item_t *item;
mca_coll_ml_topology_t *topo;
/*
* Go through each hierarchy and for each
* bcol module in the hierarchy, select the alogrithms.
*/
for (index_topo = 0; index_topo < COLL_ML_TOPO_MAX; index_topo++) {
topo = &ml_module->topo_list[index_topo];
for (i_hier = 0; i_hier < topo->n_levels; i_hier++) {
my_comm_attrib->comm_size_max =
topo->component_pairs[i_hier].subgroup_module->group_size;
for (j_bcol_module = 0;
j_bcol_module < topo->component_pairs[i_hier].num_bcol_modules;
++j_bcol_module) {
bcol_module = topo->component_pairs[i_hier].bcol_modules[j_bcol_module];
/* Go through all bcols and available bcol functions */
for (k_bcol_fn = 0; k_bcol_fn < BCOL_NUM_OF_FUNCTIONS; k_bcol_fn++) {
struct mca_bcol_base_coll_fn_desc_t *fn_filtered = NULL;
/* Query the function attributes */
fn_filtered_list =
&(bcol_module->bcol_fns_table[k_bcol_fn]);
if (0 == opal_list_get_size(fn_filtered_list)) {
continue;
}
/* All definitions of a collective type is stored in the list
* Each item in the list is checked for compatability in the
* attributes and stored in the filtered list */
for (item = opal_list_get_first(fn_filtered_list);
item != opal_list_get_end(fn_filtered_list);
item = opal_list_get_next(item)){
fn_filtered = (struct mca_bcol_base_coll_fn_desc_t *)item;
if (cmp_comm_attribs(my_comm_attrib, fn_filtered->comm_attr) < 0) {
/* Criteria not satisfied continue to next bcol function */
continue;
}
/*
* Add bcol function to be available for invoke time selection
*/
add_to_invoke_table(bcol_module, fn_filtered, ml_module);
}
}
}
}
}
return 0;
}
int mca_coll_ml_build_filtered_fn_table(mca_coll_ml_module_t *ml_module)
{
struct mca_bcol_base_coll_fn_comm_attributes_t *my_comm_attrib = NULL;
/* Init table storing all filtered functions */
init_invoke_table(ml_module);
my_comm_attrib = malloc(sizeof(struct mca_bcol_base_coll_fn_comm_attributes_t));
if (!my_comm_attrib) {
return OMPI_ERR_OUT_OF_RESOURCE;
}
my_comm_attrib->comm_size_min = 0;
/*
* This values should be passed using (maybe) mca parameters
*/
#if 0 /* Manju: pelase fix it*/
my_comm_attrib->data_src = DATA_SRC_KNOWN;
my_comm_attrib->waiting_semantics = BLOCKING;
#endif
if (build_algorithms_table(ml_module,my_comm_attrib)) {
return OMPI_ERROR;
}
return OMPI_SUCCESS;
}
#if 0
static struct mca_bcol_base_coll_fn_invoke_attributes_t *mca_construct_invoke_attributes(
struct ompi_datatype_t *dtype, int count,
struct ompi_op_t op_type)
{
size_t dt_size, msg_size;
struct mca_bcol_base_coll_fn_invoke_attributes_t *inv_attribs = NULL;
ompi_datatype_type_size(dtype, &dt_size);
msg_size = count*dt_size;
inv_attribs = malloc(sizeof(struct mca_bcol_base_coll_fn_invoke_attributes_t));
/* Fix : We might need to have range for msg size - For now selection will
* be based on maximum value
*/
inv_attribs->bcol_msg_min = 0;
inv_attribs->bcol_msg_max = msg_size;
return inv_attribs;
}
#endif
int mca_select_bcol_function(mca_bcol_base_module_t *bcol_module,
int bcoll_type,
bcol_function_args_t *bcol_fn_arguments,
coll_ml_function_t *ml_fn_arguments )
{
struct mca_bcol_base_coll_fn_desc_t *fn_filtered = NULL;
int msg_range=0;
int ret;
int data_src_type = DATA_SRC_KNOWN, waiting_type = BLOCKING;
msg_range =
count_to_msg_range(bcol_fn_arguments->count,
bcol_fn_arguments->dtype);
if ((BCOL_ALLREDUCE == bcoll_type) || (BCOL_REDUCE == bcoll_type)) {
/* needs to be resolved, the op structure has changed, there is no field called "op_type" */
/*
fn_filtered =
bcol_module->filtered_fns_table[data_src_type][waiting_type][bcoll_type][msg_range][bcol_fn_arguments->dtype->id][bcol_fn_arguments->op->op_type];
*/
}
else {
fn_filtered =
bcol_module->filtered_fns_table[data_src_type][waiting_type][bcoll_type][msg_range][bcol_fn_arguments->dtype->id][0];
}
if (NULL == fn_filtered) {
return OMPI_ERROR;
}
ret = (fn_filtered->coll_fn)(bcol_fn_arguments,ml_fn_arguments);
return ret;
}
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