/* * Copyright (c) 2004-2007 The Trustees of Indiana University and Indiana * University Research and Technology * Corporation. All rights reserved. * Copyright (c) 2004-2014 The University of Tennessee and The University * of Tennessee Research Foundation. All rights * reserved. * Copyright (c) 2004-2005 High Performance Computing Center Stuttgart, * University of Stuttgart. All rights reserved. * Copyright (c) 2004-2005 The Regents of the University of California. * All rights reserved. * Copyright (c) 2008-2009 Cisco Systems, Inc. All rights reserved. * $COPYRIGHT$ * * Additional copyrights may follow * * $HEADER$ */ /** @file */ #ifndef MCA_COLL_SM_EXPORT_H #define MCA_COLL_SM_EXPORT_H #include "ompi_config.h" #include "mpi.h" #include "ompi/mca/mca.h" #include "opal/datatype/opal_convertor.h" #include "opal/mca/common/sm/common_sm.h" #include "ompi/mca/coll/coll.h" BEGIN_C_DECLS /* Attempt to give some sort of progress / fairness if we're blocked in an sm collective for a long time: call opal_progress once in a great while. Use a "goto" label for expdiency to exit loops. */ #define SPIN_CONDITION_MAX 100000 #define SPIN_CONDITION(cond, exit_label) \ do { int i; \ if (cond) goto exit_label; \ for (i = 0; i < SPIN_CONDITION_MAX; ++i) { \ if (cond) { goto exit_label; } \ } \ opal_progress(); \ } while (1); \ exit_label: /** * Structure to hold the sm coll component. First it holds the * base coll component, and then holds a bunch of * sm-coll-component-specific stuff (e.g., current MCA param * values). */ typedef struct mca_coll_sm_component_t { /** Base coll component */ mca_coll_base_component_2_0_0_t super; /** MCA parameter: Priority of this component */ int sm_priority; /** MCA parameter: Length of a cache line or page (in bytes) */ int sm_control_size; /** MCA parameter: Number of "in use" flags in each communicator's area in the data mpool */ int sm_comm_num_in_use_flags; /** MCA parameter: Number of segments for each communicator in the data mpool */ int sm_comm_num_segments; /** MCA parameter: Fragment size for data */ int sm_fragment_size; /** MCA parameter: Degree of tree for tree-based collectives */ int sm_tree_degree; /** MCA parameter: Number of processes to use in the calculation of the "info" MCA parameter */ int sm_info_comm_size; /******* end of MCA params ********/ /** How many fragment segments are protected by a single in-use flags. This is solely so that we can only perform the division once and then just use the value without having to re-calculate. */ int sm_segs_per_inuse_flag; } mca_coll_sm_component_t; /** * Structure for representing a node in the tree */ typedef struct mca_coll_sm_tree_node_t { /** Arbitrary ID number, starting from 0 */ int mcstn_id; /** Pointer to parent, or NULL if root */ struct mca_coll_sm_tree_node_t *mcstn_parent; /** Number of children, or 0 if a leaf */ int mcstn_num_children; /** Pointer to an array of children, or NULL if 0 == mcstn_num_children */ struct mca_coll_sm_tree_node_t **mcstn_children; } mca_coll_sm_tree_node_t; /** * Simple structure comprising the "in use" flags. Contains two * members: the number of processes that are currently using this * set of segments and the operation number of the current * operation. */ typedef struct mca_coll_sm_in_use_flag_t { /** Number of processes currently using this set of segments */ volatile uint32_t mcsiuf_num_procs_using; /** Must match data->mcb_count */ volatile uint32_t mcsiuf_operation_count; } mca_coll_sm_in_use_flag_t; /** * Structure containing pointers to various arrays of data in the * per-communicator shmem data segment (one of these indexes a * single segment in the per-communicator shmem data segment). * Nothing is hard-coded because all the array lengths and * displacements of the pointers all depend on how many processes * are in the communicator. */ typedef struct mca_coll_sm_data_index_t { /** Pointer to beginning of control data */ uint32_t volatile *mcbmi_control; /** Pointer to beginning of message fragment data */ char *mcbmi_data; } mca_coll_sm_data_index_t; /** * Structure for the sm coll module to hang off the communicator. * Contains communicator-specific information, including pointers * into the per-communicator shmem data data segment for this * comm's sm collective operations area. */ typedef struct mca_coll_sm_comm_t { /* Meta data that we get back from the common mmap allocation function */ mca_common_sm_module_t *sm_bootstrap_meta; /** Pointer to my barrier control pages (odd index pages are "in", even index pages are "out") */ uint32_t *mcb_barrier_control_me; /** Pointer to my parent's barrier control pages (will be NULL for communicator rank 0; odd index pages are "in", even index pages are "out") */ uint32_t *mcb_barrier_control_parent; /** Pointers to my childrens' barrier control pages (they're contiguous in memory, so we only point to the base -- the number of children is in my entry in the mcb_tree); will be NULL if this process has no children (odd index pages are "in", even index pages are "out") */ uint32_t *mcb_barrier_control_children; /** Number of barriers that we have executed (i.e., which set of barrier buffers to use). */ int mcb_barrier_count; /** "In use" flags indicating which segments are available */ mca_coll_sm_in_use_flag_t *mcb_in_use_flags; /** Array of indexes into the per-communicator shmem data segment for control and data fragment passing (containing pointers to each segments control and data areas). */ mca_coll_sm_data_index_t *mcb_data_index; /** Array of graph nodes representing the tree used for communications */ mca_coll_sm_tree_node_t *mcb_tree; /** Operation number (i.e., which segment number to use) */ uint32_t mcb_operation_count; } mca_coll_sm_comm_t; /** Coll sm module */ typedef struct mca_coll_sm_module_t { /** Base module */ mca_coll_base_module_t super; /* Whether this module has been lazily initialized or not yet */ bool enabled; /* Data that hangs off the communicator */ mca_coll_sm_comm_t *sm_comm_data; /* Underlying reduce function and module */ mca_coll_base_module_reduce_fn_t previous_reduce; mca_coll_base_module_t *previous_reduce_module; } mca_coll_sm_module_t; OBJ_CLASS_DECLARATION(mca_coll_sm_module_t); /** * Global component instance */ OMPI_MODULE_DECLSPEC extern mca_coll_sm_component_t mca_coll_sm_component; /* * coll module functions */ int mca_coll_sm_init_query(bool enable_progress_threads, bool enable_mpi_threads); mca_coll_base_module_t * mca_coll_sm_comm_query(struct ompi_communicator_t *comm, int *priority); /* Lazily enable a module (since it involves expensive/slow mmap allocation, etc.) */ int ompi_coll_sm_lazy_enable(mca_coll_base_module_t *module, struct ompi_communicator_t *comm); int mca_coll_sm_allgather_intra(void *sbuf, int scount, struct ompi_datatype_t *sdtype, void *rbuf, int rcount, struct ompi_datatype_t *rdtype, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_allgatherv_intra(void *sbuf, int scount, struct ompi_datatype_t *sdtype, void * rbuf, int *rcounts, int *disps, struct ompi_datatype_t *rdtype, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_allreduce_intra(void *sbuf, void *rbuf, int count, struct ompi_datatype_t *dtype, struct ompi_op_t *op, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_alltoall_intra(void *sbuf, int scount, struct ompi_datatype_t *sdtype, void* rbuf, int rcount, struct ompi_datatype_t *rdtype, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_alltoallv_intra(void *sbuf, int *scounts, int *sdisps, struct ompi_datatype_t *sdtype, void *rbuf, int *rcounts, int *rdisps, struct ompi_datatype_t *rdtype, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_alltoallw_intra(void *sbuf, int *scounts, int *sdisps, struct ompi_datatype_t **sdtypes, void *rbuf, int *rcounts, int *rdisps, struct ompi_datatype_t **rdtypes, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_barrier_intra(struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_bcast_intra(void *buff, int count, struct ompi_datatype_t *datatype, int root, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_bcast_log_intra(void *buff, int count, struct ompi_datatype_t *datatype, int root, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_exscan_intra(void *sbuf, void *rbuf, int count, struct ompi_datatype_t *dtype, struct ompi_op_t *op, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_gather_intra(void *sbuf, int scount, struct ompi_datatype_t *sdtype, void *rbuf, int rcount, struct ompi_datatype_t *rdtype, int root, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_gatherv_intra(void *sbuf, int scount, struct ompi_datatype_t *sdtype, void *rbuf, int *rcounts, int *disps, struct ompi_datatype_t *rdtype, int root, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_reduce_intra(void *sbuf, void* rbuf, int count, struct ompi_datatype_t *dtype, struct ompi_op_t *op, int root, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_reduce_log_intra(void *sbuf, void* rbuf, int count, struct ompi_datatype_t *dtype, struct ompi_op_t *op, int root, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_reduce_scatter_intra(void *sbuf, void *rbuf, int *rcounts, struct ompi_datatype_t *dtype, struct ompi_op_t *op, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_scan_intra(void *sbuf, void *rbuf, int count, struct ompi_datatype_t *dtype, struct ompi_op_t *op, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_scatter_intra(void *sbuf, int scount, struct ompi_datatype_t *sdtype, void *rbuf, int rcount, struct ompi_datatype_t *rdtype, int root, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_scatterv_intra(void *sbuf, int *scounts, int *disps, struct ompi_datatype_t *sdtype, void* rbuf, int rcount, struct ompi_datatype_t *rdtype, int root, struct ompi_communicator_t *comm, mca_coll_base_module_t *module); int mca_coll_sm_ft_event(int state); /** * Global variables used in the macros (essentially constants, so * these are thread safe) */ extern uint32_t mca_coll_sm_one; /** * Macro to setup flag usage */ #define FLAG_SETUP(flag_num, flag, data) \ (flag) = (mca_coll_sm_in_use_flag_t*) \ (((char *) (data)->mcb_in_use_flags) + \ ((flag_num) * mca_coll_sm_component.sm_control_size)) /** * Macro to wait for the in-use flag to become idle (used by the root) */ #define FLAG_WAIT_FOR_IDLE(flag, label) \ SPIN_CONDITION(0 == (flag)->mcsiuf_num_procs_using, label) /** * Macro to wait for a flag to indicate that it's ready for this * operation (used by non-root processes to know when FLAG_SET() has * been called) */ #define FLAG_WAIT_FOR_OP(flag, op, label) \ SPIN_CONDITION((op) == flag->mcsiuf_operation_count, label) /** * Macro to set an in-use flag with relevant data to claim it */ #define FLAG_RETAIN(flag, num_procs, op_count) \ (flag)->mcsiuf_num_procs_using = (num_procs); \ (flag)->mcsiuf_operation_count = (op_count) /** * Macro to release an in-use flag from this process */ #define FLAG_RELEASE(flag) \ (void)opal_atomic_add(&(flag)->mcsiuf_num_procs_using, -1) /** * Macro to copy a single segment in from a user buffer to a shared * segment */ #define COPY_FRAGMENT_IN(convertor, index, rank, iov, max_data) \ (iov).iov_base = \ (index)->mcbmi_data + \ ((rank) * mca_coll_sm_component.sm_fragment_size); \ (iov).iov_len = (max_data); \ opal_convertor_pack(&(convertor), &(iov), &mca_coll_sm_one, \ &(max_data) ) /** * Macro to copy a single segment out from a shared segment to a user * buffer */ #define COPY_FRAGMENT_OUT(convertor, src_rank, index, iov, max_data) \ (iov).iov_base = (((char*) (index)->mcbmi_data) + \ ((src_rank) * (mca_coll_sm_component.sm_fragment_size))); \ (iov).iov_len = (max_data); \ opal_convertor_unpack(&(convertor), &(iov), &mca_coll_sm_one, \ &(max_data) ) /** * Macro to memcpy a fragment between one shared segment and another */ #define COPY_FRAGMENT_BETWEEN(src_rank, dest_rank, index, len) \ memcpy(((index)->mcbmi_data + \ ((dest_rank) * mca_coll_sm_component.sm_fragment_size)), \ ((index)->mcbmi_data + \ ((src_rank) * \ mca_coll_sm_component.sm_fragment_size)), \ (len)) /** * Macro to tell children that a segment is ready (normalize * the child's ID based on the shift used to calculate the "me" node * in the tree). Used in fan out opertations. */ #define PARENT_NOTIFY_CHILDREN(children, num_children, index, value) \ do { \ for (i = 0; i < (num_children); ++i) { \ *((size_t*) \ (((char*) index->mcbmi_control) + \ (mca_coll_sm_component.sm_control_size * \ (((children)[i]->mcstn_id + root) % size)))) = (value); \ } \ } while (0) /** * Macro for childen to wait for parent notification (use real rank). * Save the value passed and then reset it when done. Used in fan out * operations. */ #define CHILD_WAIT_FOR_NOTIFY(rank, index, value, label) \ do { \ uint32_t volatile *ptr = ((uint32_t*) \ (((char*) index->mcbmi_control) + \ ((rank) * mca_coll_sm_component.sm_control_size))); \ SPIN_CONDITION(0 != *ptr, label); \ (value) = *ptr; \ *ptr = 0; \ } while (0) /** * Macro for children to tell parent that the data is ready in their * segment. Used for fan in operations. */ #define CHILD_NOTIFY_PARENT(child_rank, parent_rank, index, value) \ ((size_t volatile *) \ (((char*) (index)->mcbmi_control) + \ (mca_coll_sm_component.sm_control_size * \ (parent_rank))))[(child_rank)] = (value) /** * Macro for parent to wait for a specific child to tell it that the * data is in the child's segment. Save the value when done. Used * for fan in operations. */ #define PARENT_WAIT_FOR_NOTIFY_SPECIFIC(child_rank, parent_rank, index, value, label) \ do { \ size_t volatile *ptr = ((size_t volatile *) \ (((char*) index->mcbmi_control) + \ (mca_coll_sm_component.sm_control_size * \ (parent_rank)))) + child_rank; \ SPIN_CONDITION(0 != *ptr, label); \ (value) = *ptr; \ *ptr = 0; \ } while (0) END_C_DECLS #endif /* MCA_COLL_SM_EXPORT_H */